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Course 1: Civil and Environmental Engineering
Fall 2016


Fundamentals

1.00 Engineering Computation and Data Science
______

Undergrad (Spring) Rest Elec in Sci & Tech
(Subject meets with1.001)
Prereq: Calculus I (GIR)
Units: 5-1-6
______

1.000 Computer Programming for Scientific and Engineering Applications
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: None.Coreq: 18.03
Units: 3-2-7
Lecture: MWF3-4.30 (5-233) Lab: TBA +final
______
Presents the fundamentals of computing and computer programming (procedural and object-oriented programming) in an engineering context. Introduces logical operations, floating-point arithmetic, data structures, induction, iteration, and recursion. Computational methods for interpolation, regression, root finding, sorting, searching, and the solution of linear systems of equations and ordinary differential equations. Control of sensors and visualization of scientific data. Draws examples from engineering and scientific applications. Students use the MATLAB programming environment to complete weekly assignments.
R. Juanes
No textbook information available

1.001 Engineering Computation and Data Science
______

Graduate (Spring)
(Subject meets with1.00)
Prereq: Calculus I (GIR)
Units: 5-1-6
______
Presents fundamentals of computing and programming in an engineering context with an emphasis on data science. Introduces basics of web computing, data structures, and techniques for data analysis. Includes filtering, linear regression, simple machine learning (clustering and classifiers), and visualization. Surveys techniques for ingesting, processing, analyzing, and visualizing engineering data from a range of fields, including geo-spatial, environment, infrastructure, city dynamics, and numerical experiments. Students use JavaScript and HTML5 programming language to complete weekly assignments. Students taking graduate version complete additional assignments.
J. Williams

1.007 Big Engineering: Small Solutions with a Large Impact
______

Undergrad (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Provides a practical introduction to key topics, current research and innovative methods in the diverse field of civil and environmental engineering. Discusses career opportunities, innovation, and entrepreneurship. Under faculty supervision, students work on projects in areas such as renewable energy, sustainable design, food security, climate change, and transportation. Projects focus on design of novel solutions to grand challenges related to infrastructure, systems and the environment, and include elements of the different areas to demonstrate the interconnectedness of the discipline. Preference to first-year students and Course 1 sophomores.
B. Marelli

1.010 Uncertainty in Engineering
______

Undergrad (Fall)
Prereq: Calculus II (GIR)
Units: 5-0-7
Lecture: TR9.30-11 (1-242) Recitation: F9-11 (1-242) +final
______
Introduces probability and statistics with an emphasis on understanding, quantifying, and modeling uncertainty. Topics include events and their probability, the total probability and Bayes' theorems, discrete and continuous random variables and vectors, covariance, correlations, and conditional analysis. Random sampling, estimation of distribution parameters (method of moments, maximum likelihood, Bayesian estimation), and simple and multiple linear regression. Concepts illustrated with examples from various areas of engineering and everyday life. Integrates applications with statistical computing and graphics.
S. Saavedra
Textbooks (Fall 2016)

1.011 Project Evaluation and Management
______

Undergrad (Spring)
Prereq: None
Units: 3-1-8
______
Develops skills to evaluate a project or program using economic, environmental, and equity metrics, and to plan, execute and manage its progress to completion. Introduces students to engineering projects that are typically large-scale and long-lived, and involve many economic, financial, social and environmental factors. Covers net present value analysis, life-cycle costing, and benefit-cost analysis. Culminates in a term project in which small teams study a historical or prospective project of their choosing. Instruction and practice in oral and written communication provided.
J. Sussman

1.013 Senior Civil and Environmental Engineering Design
______

Undergrad (Spring)
Prereq: Permission of instructor
Units: 2-6-4
______
Students engage with faculty around a topic of mutual interest, building on the knowledge/skills gained throughout their program. Synthesizes prior coursework and experiences through a semester-long design project and related assignments. Students form teams to work on projects of their choosing, focusing in depth on the diverse areas within civil and environmental engineering. Teams demonstrate creativity in applying theories and methodologies while considering their project's technical, environmental and social feasibility. Includes lectures on a variety of related engineering concepts, as well as scholarship and engineering practice and ethics. Provides instruction and practice in oral and written communication.
H. Hemond

1.015[J] Design of Electromechanical Robotic Systems
______

Undergrad (Spring) 1/2 Institute Lab
(Same subject as2.017[J])
Prereq: 2.003 or 2.03;Coreq: 2.005, 2.05 and 2.051, or 2.016; 2.671
Units: 3-3-6
______
Design, construction, and testing of field robotic systems, through team projects with each student responsible for a specific subsystem. Projects focus on electronics, instrumentation, and machine elements. Design for operation in uncertain conditions is a focus point, with ocean waves and marine structures as a central theme. Basic statistics, linear systems, Fourier transforms, random processes, spectra and extreme events with applications in design. Lectures on ethics in engineering practice included. Enrollment may be limited due to laboratory capacity.
F. S. Hover, J. J. Leonard

1.016 Design for Complex Environmental Issues: Building Solutions and Communicating Ideas
______

Undergrad (Spring)
Prereq: None
Units: 3-1-5
______
Students work in small groups, under the guidance of researchers from MIT, to pursue specific aspects of the year's Terrascope problem. Teams design and build prototypes, graphic displays and other tools to communicate their findings and display them in a Bazaar of Ideas open to the MIT community. Some teams develop particular solutions, others work to provide deeper understanding of the issues, and others focus on ways to communicate these ideas with the general public. Students' work is evaluated by independent experts. Offers students an opportunity to develop ideas from the fall semester and to work in labs across MIT. Limited to first-year students.
C. Harvey

1.018A[J] Fundamentals of Ecology I
______

Undergrad (Fall); first half of term
(Same subject as7.30A[J],12.031A[J])
Prereq: None
Units: 2-0-4
Ends Oct 21. Lecture: TR11-12.30 (48-316) Recitation: M4 (48-316) or R4 (48-308)
______
Fundamentals of ecology, considering Earth as an integrated dynamic living system. Coevolution of the biosphere and geosphere, biogeochemical cycles, metabolic diversity, primary productivity, competition and the niche, trophic dynamics and food webs, population growth and limiting factors. Combination of 1.018A and 1.018B counts as REST subject.
O. Cordero, M. Follows
No required or recommended textbooks

1.018B[J] Fundamentals of Ecology II
______

Undergrad (Fall); second half of term
(Same subject as7.30B[J],12.031B[J])
Prereq: 1.018A
Units: 2-0-4
Begins Oct 24. Lecture: TR11-12.30 (48-316) Recitation: M4 (48-316) or R4 (48-308) +final
______
Advanced topics in Ecology. Population modeling, global carbon cycle, climate change, geoengineering, theories of resource competition and mutualism, allometric scaling, ecological genomics, niche theory, human population growth. Applied ecology. Combination of 1.018A and 1.018B counts as REST subject.
O. Cordero, M. Follows
No required or recommended textbooks

1.020 Principles of Energy and Water Sustainability
______

Undergrad (Spring)
Prereq: Physics I (GIR);Coreq: 18.03 or permission of instructor
Units: 3-2-7
______
Introduces a systems approach to modeling, analysis, and decision-making problems for water and energy sustainability; formulation of models based on physical, environmental, social, and economic principles; and economic evaluation of design. Covers applications of mass balance, energy balance, and economic and lifecycle concepts. Uses numerical models to integrate concepts and to assess environmental impacts of human activities.
S. Amin

1.021 Introduction to Modeling and Simulation
______

Undergrad (Spring) Rest Elec in Sci & Tech
Engineering School-Wide Elective Subject.
(Offered under:1.021,3.021,10.333,22.00)
Prereq: 18.03, 3.016, or permission of instructor
Units: 4-0-8
______
Basic concepts of computer modeling and simulation in science and engineering. Uses techniques and software for simulation, data analysis and visualization. Continuum, mesoscale, atomistic and quantum methods used to study fundamental and applied problems in physics, chemistry, materials science, mechanics, engineering, and biology. Examples drawn from the disciplines above are used to understand or characterize complex structures and materials, and complement experimental observations.
M. Buehler, R. Taylor

1.022 Urban Networks
______

Undergrad (Fall); second half of term
Prereq: 1.00 or 1.000; 1.010
Units: 3-0-3
Begins Oct 31. Lecture: TR1-2.30 (1-150) Recitation: F1 (1-150)
______
Introduces the structure and evolution of networks with examples from engineering, applied mathematics, computer science, and statistical physics. Includes analysis of real world datasets focused on identifying important nodes in networks, detecting communities, tracing network flows, and modeling and visualization of spatial networks.
M. Gonzalez
No required or recommended textbooks

1.032 Advanced Soil Mechanics
______

Undergrad (Fall); first half of term
(Subject meets with1.361)
Prereq: 1.010, 1.011, 1.036
Units: 3-0-6
Ends Oct 21. Lecture: TR10.30-12 (1-246) Recitation: W4 (1-273) +final
______
Covers topics in the characterization and nature of soils as multi-phase materials; the principle of effective stress; hydraulic conductivity and groundwater seepage; shear strength and stability analyses; stress-deformation properties, consolidation theory and calculation of settlements for clays and sands. Students taking graduate version complete additional assignments.
A. Whittle
No required or recommended textbooks

1.035 Multiscale Characterization of Materials
______

Undergrad (Spring)
Prereq: 1.050, 18.03
Units: 3-3-6
______
Introduces the structure and properties of natural and manufactured building materials. Emphasizes effects of molecular and nanoscopic structure and interactions on macroscopic material behavior. Focuses on design of biological and artificial structural materials. Discusses material aspects of sustainable development. Includes durability, deterioration mechanisms, and damage assessment of building materials. Presents principles of experimental characterization techniques. Explores spectroscopic, microscopic and mechanical approaches to characterize structure and properties from molecular up to the macroscopic scale. In laboratory and in-field sessions, students design and implement experimental approaches to characterize natural and building materials and study their interaction with the environment.
F. Ulm

1.036 Structural Mechanics and Design
______

Undergrad (Spring)
Prereq: 1.035, 1.050
Units: 3-1-8
______
Familiarizes students with structural systems, loads, and basis for structural design, including analysis of determinate and indeterminate structures (trusses, beams, frames, cables, and arches). Covers mechanical properties of construction materials, including concrete, steel, and composites. Studies concrete and steel structures through application of principles of structural mechanics. Evaluates behavior and design of reinforced concrete structural elements using limit strength design and serviceability principles. Introduces plastic analysis and design, and load factor design of structural steel members and connections. Team project emphasizes material covered through behavior and problem-based learning.
O. Buyukozturk

1.037 Soil Mechanics and Geotechnical Design
______

Undergrad (Spring)
Prereq: None
Units: 3-2-7
______
Provides an introduction to soils as engineering materials, including classification and characterization, pore pressures and seepage, principles of effective stress and consolidation, deformation, and shear strength properties. Surveys analysis methods, with a focus on slope stability, limiting earth pressures and bearing capacity, and settlements of foundations. Examines applications in the design of earth dams, earth retaining systems, foundations, and staged construction processes.
A. Whittle

1.041 Transportation Systems Modeling
______

Undergrad (Spring)
Prereq: 1.00 or 1.000; 1.010
Units: 3-1-8
______
Introduces basic concepts of transportation systems modeling, data analysis and visualization techniques. Covers fundamental analytical and simulation-based methodologies. Topics include time-space diagrams, cumulative plots, queueing theory, network science, data analysis, and their applications. Provides students with an understanding of the current challenges and opportunities in different areas of transportation.
C. Osorio

1.044[J] Fundamentals of Energy in Buildings
______

Not offered academic year 2016-2017Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject as2.66[J],4.42[J])
Prereq: Physics I (GIR), Calculus II (GIR)
Units: 3-2-7
______
Design-based introduction to energy and thermo-sciences, with applications to sustainable, energy-efficient architecture and building technology. Covers introductory thermodynamics, air/water/vapor mixtures, and heat transfer. Studies leading order factors in building energy use. Includes several building design projects in which students creatively employ energy fundamentals and building energy use.
L. R. Glicksman

1.050 Solid Mechanics
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Physics I (GIR);Coreq: Calculus II (GIR)
Units: 3-2-7
Lecture: MWF11 (4-231) Lab: R3-5 (5-217) +final
______
Basic principles of mechanics to describe the behavior of materials, structures and fluids. Dimensional analysis, conservation of momentum, static equilibrium, stress and stress states, hydrostatics, moments and forces. Material and structural strength criteria. Deformation and strain. Conservation of energy in solid mechanics, elasticity and elasticity bounds. Energy dissipation, plasticity and fracture. Open-ended geotechnical and structural engineering studio exercises and experiments with natural and man-made physical systems.
F. J. Ulm
No required or recommended textbooks

1.053[J] Dynamics and Control I
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
(Same subject as2.003[J])
Prereq: Physics II;Coreq: 18.03 or 2.087
Units: 4-1-7
Lecture: TR9.30-11 (10-250) Recitation: R12 (5-233) or R1 (5-233) or R3 (5-233) or R4 (5-233) or F2 (1-246) or F3 (1-246) +final
______
Introduction to the dynamics and vibrations of lumped-parameter models of mechanical systems. Kinematics. Force-momentum formulation for systems of particles and rigid bodies in planar motion. Work-energy concepts. Virtual displacements and virtual work. Lagrange's equations for systems of particles and rigid bodies in planar motion. Linearization of equations of motion. Linear stability analysis of mechanical systems. Free and forced vibration of linear multi-degree of freedom models of mechanical systems; matrix eigenvalue problems.
J. K. Vandiver, N. C. Makris, N. M. Patrikalakis, T. Peacock, D. Gossard, K. Turitsyn
No required or recommended textbooks

1.054 Mechanics and Design of Concrete Structures
______

Undergrad (Fall)
(Subject meets with1.541)
Prereq: 1.035
Units: 3-0-9
Lecture: MW1-2.30 (1-246)
______
Studies strength and deformation of concrete under various states of stress; failure criteria; concrete plasticity; and fracture mechanics concepts. Topics include fundamental behavior of reinforced concrete structural systems and their members; basis for design and code constraints; high-performance concrete materials and their use in innovative design solutions; and yield line theory for slabs. Uses behavior models and nonlinear analysis. Covers complex systems, including bridge structures, concrete shells, and containments. Students taking graduate version complete additional assignments.
O. Buyukozturk
Textbooks (Fall 2016)

1.056[J] Building Structural Systems I
______

Undergrad (Spring) Rest Elec in Sci & Tech
(Same subject as4.440[J])
(Subject meets with4.462)
Prereq: Calculus II (GIR)
Units: 3-3-6
______
Introduces the design and behavior of large-scale structures and structural materials. Emphasizes the development of structural form and the principles of structural design. Presents design methods for timber, masonry, concrete and steel applied to long-span roof systems, bridges, and high-rise buildings. Includes environmental assessment of structural systems and materials. In laboratory sessions, students solve structural problems by building and testing simple models. Graduate and undergraduate students have separate lab sections.
J. Ochsendorf

1.058 Structural Dynamics & Vibrations
______

Undergrad (Fall)
(Subject meets with1.581[J],2.060[J],16.221[J])
Prereq: Permission of instructor
Units: 3-1-8
Lecture: MWF10 (1-390) Recitation: W4 (1-246)
______
Single- and multiple-degree-of-freedom vibration problems, using matrix formulation and normal mode superposition methods. Time and frequency domain solution techniques including convolution and Fourier transforms. Applications to vibration isolation, damping treatment, and dynamic absorbers. Analysis of continuous systems by exact and approximate methods. Applications to buildings, ships, aircraft and offshore structures. Vibration measurement and analysis techniques. Students should possess basic knowledge in structural mechanics and in linear algebra. Students taking graduate version complete additional assignments.
E. Kausel
No textbook information available

1.060A Fluid Mechanics I
______

Undergrad (Fall); first half of term
Prereq: Permission of instructor orCoreq: 18.03
Units: 2-1-3
Ends Oct 21. Lecture: MWF11 Lab: T10-12 or F2.30-4.30
______
Mechanics principles for incompressible fluids. Review of hydrostatics. Conservation of mass, momentum and energy in fluid mechanics. Flow nets, velocity distributions in laminar and turbulent flows, groundwater flows. Momentum and energy principles in hydraulics, with emphasis on open channel flow and hydraulic structures.
B. Marelli
Textbooks (Fall 2016)

1.060B Fluid Mechanics II
______

Undergrad (Fall); second half of term
Prereq: 1.060A
Units: 2-1-3
Begins Oct 24. Lecture: MWF11 Lab: T10-12 or F2.30-4.30 +final
______
Mechanics principles for incompressible fluids. Drag and lift forces. Analysis of pipe systems, pumps and turbines. Gradually varied flow in open channels, significance of the Froude number, backwater curves. Application of principles through open-ended studio exercises.
B. Marelli
Textbooks (Fall 2016)

1.061 Transport Processes in the Environment
______

Undergrad (Fall)
(Subject meets with1.61)
Prereq: 1.060B
Units: 3-1-8
Lecture: MWF10 (48-316) Recitation: F11 (48-316) +final
______
Introduction to mass transport in environmental flows, with emphasis on river and lake systems. Covers derivation and solutions to the differential form of mass conservation equations, hydraulic models for environmental systems, residence time distribution, molecular and turbulent diffusion for continuous and point sources, boundary layers, dissolution, bed-water exchange, air-water exchange, and particle transport. Meets with 1.061A first half of term. Students taking graduate version complete additional assignments.
H. M. Nepf
No required or recommended textbooks

1.061A Transport Processes in the Environment I
______

Undergrad (Fall); first half of term
Prereq: 1.060A
Units: 2-1-3
Ends Oct 21. Lecture: MWF10 (48-316) Recitation: F11 (48-316)
______
Introduction to mass transport in environmental flows. Covers derivation and solution to the differential form of mass conservation, hydraulic models for environmental systems, residence time distribution, and molecular and turbulent diffusion for continuous and point sources. Meets with 1.061 first half of term.
H. Nepf
No required or recommended textbooks

1.062[J] Nonlinear Dynamics: Continuum Systems
______

Undergrad (Spring)
(Same subject as12.207[J],18.354[J])
(Subject meets with18.3541)
Prereq: 18.03 or 18.034; Physics II (GIR)
Units: 3-0-9
______
General mathematical principles of continuum systems. From microscopic to macroscopic descriptions in the form of linear or nonlinear (partial) differential equations. Exact solutions, dimensional analysis, calculus of variations and singular perturbation methods. Stability, waves and pattern formation in continuum systems. Subject matter illustrated using natural fluid and solid systems found, for example, in geophysics and biology.
P. Pearce

1.064 Physical Limnology
______

Undergrad (Spring)
Not offered regularly; consult department
(Subject meets with1.64)
Prereq: 1.061
Units: 3-0-9
______
Provides an introduction to physical processes occurring in lakes and shallow surface water systems with emphasis on mechanisms affecting fate and transport. Topics include internal waves, differential heating and cooling, boundary mixing, turbulent mixing, and influence of vegetation. Begins with a review of Navier-Stokes equation. Students taking graduate version complete additional assignments.
H. M. Nepf

1.068 Nonlinear Dynamics and Turbulence
______

Not offered academic year 2017-2018Undergrad (Spring)
(Subject meets with1.686[J],18.358[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Reviews theoretical notions of nonlinear dynamics, instabilities, and waves with applications in fluid dynamics. Discusses hydrodynamic instabilities leading to flow destabilization and transition to turbulence. Focuses on physical turbulence and mixing from homogenous isotropic turbulence. Also covers topics such as rotating and stratified flows as they arise in the environment, wave-turbulence, and point source turbulent flows. Students taking graduate version complete additional assignments.
L. Bourouiba

1.070A[J] Introduction to Hydrology and Water Resources
______

Undergrad (Fall); first half of term
(Same subject as12.320A[J])
Prereq: 1.060A;Coreq: 1.061A, 1.106
Units: 2-0-4
Ends Oct 21. Lecture: TR9.30-11 (48-316) Recitation: M1 (48-308)
______
Water in the environment; Water resource systems; The hydrologic cycle at its role in the climate system; Surface water and energy balance; evaporation and transpiration through vegetation; Precipitation formation, infiltration, storm runoff, and flood processes; Groundwater aquifers, subsurface flow and the hydraulics of wells.
D. Entekhabi
No textbook information available

1.070B[J] Introduction to Hydrology Modeling
______

Undergrad (Fall); second half of term
(Same subject as12.320B[J])
Prereq: 1.070A
Units: 2-0-4
Begins Oct 24. Lecture: TR9.30-11 (48-316) Recitation: M1 (48-308)
______
Develops understanding of numerical modeling of aquifers, groundwater flow and contaminant transport, as well as uncertainty and risk analysis for water resources.
D. Entekhabi
No textbook information available

1.071[J] Global Change Science
______

Not offered academic year 2016-2017Undergrad (Fall)
(Same subject as12.300[J])
Prereq: 18.03
Units: 3-0-9
______
Introduces the basic relevant principles and concepts in atmospheric physics, climate dynamics, biogeochemistry, and water and energy balance at the land-atmosphere boundary, through an examination of two current problems in the global environment: carbon dioxide and global warming; and tropical deforestation and regional climate. An introduction to global environmental problems for students in basic sciences and engineering.
E. A. B. Eltahir

1.072 Groundwater Hydrology
______

Undergrad (Fall)
(Subject meets with1.72)
Prereq: 1.061
Units: 3-1-8
Lecture: MW2.30-4 (48-308) Recitation: TBA +final
______
Presents the fundamentals of subsurface flow and transport, emphasizing the role of groundwater in the hydrologic cycle, the relation of groundwater flow to geologic structure, and the management of contaminated groundwater. Topics include Darcy equation, flow nets, mass conservation, the aquifer flow equation, heterogeneity and anisotropy, storage properties, regional circulation, unsaturated flow, recharge, stream-aquifer interaction, well hydraulics, flow through fractured rock, numerical models, groundwater quality, contaminant transport processes, dispersion, decay, and adsorption. Includes laboratory and computer demonstrations. Students taking graduate version complete additional assignments.
C. Harvey
No textbook information available

1.073 Introduction to Environmental Data Analysis
______

Not offered academic year 2016-2017Undergrad (Spring); first half of term
Prereq: 1.010
Units: 2-0-4
______
Covers theory and practical methods for the analysis of univariate data sets. Topics include basics of statistical inference, analysis of trends and stationarity; Gaussian stochastic processes, covariance and correlation analysis, and introduction to spectral analysis. Students analyze data collected from the civil, environment, and systems domains.
E. Eltahir

1.074 Multivariate Data Analysis
______

Undergrad (Spring); second half of term
Prereq: 1.010
Units: 2-0-4
______
Introduction to statistical multivariate analysis methods and their applications to analyze data and mathematical models. Topics include sampling, experimental design, regression analysis, specification testing, dimension reduction, categorical data analysis, classification and clustering.
Staff

1.075 Water Resource Systems
(New)
______

Undergrad (Fall)
(Subject meets with1.731)
Prereq: 1.070B or permission of instructor
Units: 3-0-9
Lecture: TR2.30-4 (48-316) +final
______
Surveys optimization and simulation methods for management of water resources. Case studies illustrate linear, quadratic, nonlinear programming and real-time control. Applications include river basin planning, irrigation and agriculture, reservoir operations, capacity expansion, assimilation of remote sensing data, and sustainable resource development. Students taking graduate version complete additional assignments.
D. McLaughlin
No textbook information available

1.078 Introduction to Soil Science
(New)
______

Undergrad (Fall)
(Subject meets with1.78)
Prereq: None
Units: 3-1-8
Lecture: TR1-2.30 (48-308) Recitation: R4 (48-109) +final
______
Presents the physical, chemical, biological and genetic properties of soils, their global distribution, and response to management. Emphasizes factors controlling soil development, plant productivity, and the fate, cycling and bioavailability of soil nutrients and pollutants. Introduces Earth's different soil types and their classification; links characteristics with contemporary and historic issues surrounding natural and managed soil systems. Topics include soil carbon cycling, water and fertilizer management, and challenges associated with soil salinity-sodicity, erosion, and pollution. Includes field trips to local sites to examine soil physical properties, classification, and function. Introductory biology and chemistry are recommended prerequisites. Students taking graduate version complete additional assignments.
B. Kocar
Textbooks (Fall 2016)

1.080A Environmental Chemistry I
______

Undergrad (Spring); first half of term
Prereq: Chemistry (GIR)
Units: 2-0-4
______
Introduction to environmental chemistry with a focus on using thermodynamics to understand processes governing chemical behaviors in natural and engineered systems. Topics include vaporization, gas-solution partitioning, salt and mineral dissolution/precipitation, acid-base chemistry, metal complexation, adsorption via ion exchange, and absorption within natural organic matter and organism tissues. Process formulations are combined in box models to compare with observations.
P. M. Gschwend

1.080B Environmental Chemistry II
______

Undergrad (Spring); second half of term
Prereq: 1.080A
Units: 2-0-4
______
Intermediate topics in environmental chemistry requiring kinetics to understand processes governing biogeochemical behaviors in natural and engineered systems. Topics include radiochemistry, redox chemistry, surface chemistry and surface complexation. Introduction to geochemical modeling using reactive transport software; process formulations are combined in chemical fate models to compare with observations of concentrations as a function of space and time.
J. Kroll

1.081[J] Environmental Cancer Risks, Prevention, and Therapy
______

Undergrad (Spring)
(Same subject as20.104[J])
Prereq: Calculus II (GIR), Biology (GIR), Chemistry (GIR)
Units: 3-0-9
______
Analysis of the history of cancer and vascular disease mortality rates in predominantly European- and African-American US cohorts, 1895-2010, to discover specific historical shifts. Shifts identified are explored in terms of contemporaneously changing environmental risk factors: air-, food- and water-borne chemicals; subclinical infections; diet and lifestyles. Role of occupational data identifying general risk factors. Considers the hypotheses that environmental factors affect metakaryotic stem cell mutation rates in fetuses and juveniles and/or the growth rates of preneoplastic stem cells in adults. Interaction of environmental and inherited risks. Introduces the use of metakaryocidal drugs to treat cancer in clinical trials.
W. Thilly, R. McCunney

1.082 Ethics for Engineers
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.082,2.900,6.904,10.01,22.014)
Prereq: None
Units: 2-0-4
Lecture: M3-5 (66-144, 36-153) or T3-5 (37-212) or T EVE (7.30-9.30 PM) (66-144) or W3-5 (36-153)
______
Integrates classical readings that provide an overview of ethics with a survey of case studies that focus on ethical problems arising in the practice of engineering. Readings taken from a variety of sources, such as Aristotle, Machiavelli, Bacon, Hobbes, Locke, the Founding Fathers, and the Bible. Case studies include written analyses and films that address engineering disasters, biotechnology, court cases, ethical codes, and the ultimate scope and aims of engineering.
D. Doneson, B. L. Trout
No textbook information available

1.084[J] Systems Microbiology
______

Undergrad (Fall)
(Same subject as20.106[J])
Prereq: Chemistry (GIR), Biology (GIR)
Units: 3-0-9
Lecture: TR2.30-4 (56-614)
______
Introductory microbiology from a systems perspective - considers microbial diversity and the integration of data from a molecular, cellular, organismal, and ecological context to understand the interaction of microbial organisms with their environment. Special emphasis on specific viral, bacterial, and eukaryotic microorganisms and their interaction with animal hosts with focus on contemporary problems in areas such as vaccination, emerging disease, antimicrobial drug resistance, and toxicology.
E. Alm, J. Niles
No textbook information available

1.085[J] Air Pollution
______

Undergrad (Fall)
(Same subject as12.336[J])
Prereq: 18.03
Units: 3-0-9
Lecture: MW10.30-12 (48-308)
______
Provides a working knowledge of basic air quality issues, with emphasis on a multidisciplinary approach to investigating the sources and effects of pollution. Topics include emission sources; atmospheric chemistry and removal processes; meteorological phenomena and their impact on pollution transport at local to global scales; air pollution control technologies; health effects; and regulatory standards. Discusses regional and global issues, such as acid rain, ozone depletion and air quality connections to climate change.
C. Heald
Textbooks (Fall 2016)

1.089 Environmental Microbiology
______

Undergrad (Spring)
(Subject meets with1.89)
Prereq: Biology (GIR)
Units: 3-0-9
______
Provides a general introduction to the diverse roles of microorganisms in natural and artificial environments. Topics include energetics and growth, evolution and gene flow, population and community dynamics, water and soil microbiology, biogeochemical cycling, and microorganisms in biodeterioration and bioremediation. 7.014 recommended as prerequisite; students taking graduate version complete additional assignments. Meets with 1.089A first half of term.
M. Polz, O. Cordero

1.089A Environmental Microbiology I
(New)
______

Undergrad (Spring); first half of term
Prereq: Biology (GIR) or permission of instructor
Units: 3-0-3
______
Provides a general introduction to the diverse roles of microorganisms in natural and artificial environments. Topics include energetics, and growth; metabolic interactions; water and soil microbiology; biogeochemical cycling; microbial diversity. 7.014 recommended as prerequisite. Meets with 1.089 first half of term.
M. Polz, O. Cordero

1.091 Traveling Research Environmental eXperience (TREX): Fieldwork
______

Undergrad (IAP)
Prereq: Permission of instructor
Units: 1-2-0
______
Introduction to environmental fieldwork and research, with a focus on data collection and analysis. Subject spans three weeks, including two weeks of fieldwork, and involves one or more projects central to environmental science and engineering. Location varies year-to-year, though recent projects have focused on the island of Hawaii. Limited to Course 1 students.
B. Kocar

1.092 Traveling Research Environmental eXperience (TREX): Fieldwork Analysis and Communication
______

Undergrad (Spring)
Prereq: 1.091
Units: 1-3-5
______
Building on fieldwork and research conducted in 1.091 over IAP, students focus on interpretation of results and research in support of the fieldwork, with instruction and practice in oral and written communication. Includes a survey of the relevant peer-reviewed literature; laboratory measurements of field samples and/or instrumental response; data analysis and interpretation; and dissemination of results. Culminates in presentation of research project(s), and write-ups of the research in manuscript form. Sequence of 1.091 and 1.092 must be completed in consecutive terms. Limited to Course 1 majors and minors.
B. Kocar

1.095 Teaching Practicum in Civil and Environmental Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Students work as unpaid laboratory, tutorial, or classroom assistants under supervision of a faculty member. Limited to Undergraduate Teaching Fellows and graders in Course 1.
Staff
No textbook information available

1.097 Introduction to Civil and Environmental Engineering Research
______

Undergrad (IAP)
Prereq: None
Units: 1-5-0 [P/D/F]
______
Students work one-on-one with a CEE graduate student or postdoc mentor on a project that aligns with their research interests. Previous project topics include transportation networks, structural mechanics, sediment transport, climate science, and microbial ecology. Includes weekly seminar-style talks. Intended for first-year students.
Staff

Undergraduate Laboratory Subjects

1.101 Introduction to Civil and Environmental Engineering Design I
______

Undergrad (Fall) 1/2 Institute Lab
Prereq: None
Units: 0-4-2
Lab: TR1-3 (1-050)
______
Introduces the creative design process in the context of civil and environmental engineering. Emphasizes the idea-to-product trajectory: identification of a design question/problem, evaluation of requirements/constraints set by the application and/or client, and implementation into a concrete product deliverable. Fosters active learning through open-ended, student-driven projects in which teams apply the design process to a design/planning problem. In labs, students design and build a working model or an experiment that addresses a specific engineering aspect of their project. In addition to written and oral presentations, students start a web-based portfolio. Enrollment limited; preference to Course 1 majors and minors.
P. Reis
No required or recommended textbooks

1.102 Introduction to Civil and Environmental Engineering Design II
______

Undergrad (Spring) 1/2 Institute Lab
Prereq: Physics II (GIR); orCoreq: 1.060B and permission of instructor
Units: 1-3-2
______
Project-oriented subject focused on the principles and practice of engineering design. Emphasis on construction and deployment of designs, plus performance testing used to determine if designs behave as expected. Includes a major team project involving use and application of sensors, as well as environmentally-friendly, and energy-effective or energy-producing designs. Develops practical, teamwork and communication skills. Enrollment limited; preference to Course 1 majors and minors.
A. Masic

1.106 Environmental Fluid Transport Processes and Hydrology Laboratory
______

Undergrad (Fall) 1/2 Institute Lab
Prereq: None.Coreq: 1.061A, 1.070A
Units: 0-4-2
Lab: W1-5 (48-109)
______
Fundamentals of mass transport and flow measurements in the context of environmental systems. Topics include measurement uncertainty, propagation of error, diffusion, dispersion, air-water exchange, dissolution, gravity currents, particle transport, and transport in porous media. Includes formal lab reports. Enrollment limited; preference to 1-ENG.
H. Nepf, D. Entekhabi
No required or recommended textbooks

1.107 Environmental Chemistry and Biology Laboratory
______

Undergrad (Spring) 1/2 Institute Lab
Prereq: 1.018A or permission of instructor;Coreq: 1.080A
Units: 0-4-2
______
Laboratory and field techniques in biogeochemistry and environmental engineering and their application to the understanding of natural and engineered ecosystems. Exercises demonstrate data acquisition and modeling suited to identifying and quantifying physical, chemical, and biological processes that govern the effects of human activity on the functioning of natural systems and/or the efficacy of engineered approaches to environmental problems. Applications include chemical and biological remediation, measurement of contaminants, and detection of biogeochemical activity in natural environments. An independently designed final project is required. Enrollment limited; preference to 1-ENG.
P. Gschwend, B. Kocar

Engineering Information Systems and Computation

1.124[J] Software and Computation for Simulation
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as2.091[J])
Prereq: 1.00 or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/1.124/www/
______
Modern software development techniques and algorithms for engineering computation. Hands-on investigation of computational and software techniques for simulating engineering systems, such as sensor networks, traffic networks, and discrete simulation of materials using atomistic and particle methods. Covers data structures and algorithms for modeling, analysis, and visualization in the setting of multi-core and distributed computing. Treatment of basic topics, such as queuing, sorting and search algorithms, and more advanced numerical techniques based on state machines and distributed agents. Foundation for in-depth exploration of image processing, optimization, finite element and particle methods, computational materials, discrete element methods, and network methods. Knowledge of an object-oriented language required.
J. R. Williams

1.125 Architecting & Engineering Software Systems
______

Graduate (Fall)
Prereq: 1.00, 1.124J, or permission of instructor
Units: 3-0-9
Lecture: TR12.30-2 (48-316)
______
Software architecting and design of software-intensive systems. Targeted at future CTOs who must understand both the business and technical issues involved in architecting enterprise-scale systems. Student teams confront technically challenging problems. Lectures and readings cover core database, XML, web server components and browser issues in a distributed web service environment. Enrollment limited.
J. Williams
No required or recommended textbooks

1.126[J] Pattern Recognition and Analysis
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject asMAS.622[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Fundamentals of characterizing and recognizing patterns and features of interest in numerical data. Basic tools and theory for signal understanding problems with applications to user modeling, affect recognition, speech recognition and understanding, computer vision, physiological analysis, and more. Decision theory, statistical classification, maximum likelihood and Bayesian estimation, nonparametric methods, unsupervised learning and clustering. Additional topics on machine and human learning from active research. Knowledge of probability theory and linear algebra required. Limited to 20.
R. W. Picard

1.128[J] Computational Geometry
______

Graduate (Spring)
Not offered regularly; consult department
(Same subject as 2.089[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Topics in surface modeling: b-splines, non-uniform rational b-splines, physically based deformable surfaces, sweeps and generalized cylinders, offsets, blending and filleting surfaces. Non-linear solvers and intersection problems. Solid modeling: constructive solid geometry, boundary representation, non-manifold and mixed-dimension boundary representation models, octrees. Robustness of geometric computations. Interval methods. Finite and boundary element discretization methods for continuum mechanics problems. Scientific visualization. Variational geometry. Tolerances. Inspection methods. Feature representation and recognition. Shape interrogation for design, analysis, and manufacturing. Involves analytical and programming assignments.
N. M. Patrikalakis, D. C. Gossard

Engineering Analysis Methods

1.138[J] Wave Propagation
______

Graduate (Spring)
(Same subject as2.062[J],18.376[J])
Prereq: 2.003, 18.075
Units: 3-0-9
URL: http://math.mit.edu/classes/18.376/
______
Theoretical concepts and analysis of wave problems in science and engineering with examples chosen from elasticity, acoustics, geophysics, hydrodynamics, blood flow, nondestructive evaluation, and other applications. Progressive waves, group velocity and dispersion, energy density and transport. Reflection, refraction and transmission of plane waves by an interface. Mode conversion in elastic waves. Rayleigh waves. Waves due to a moving load. Scattering by a two-dimensional obstacle. Reciprocity theorems. Parabolic approximation. Waves on the sea surface. Capillary-gravity waves. Wave resistance. Radiation of surface waves. Internal waves in stratified fluids. Waves in rotating media. Waves in random media.
T. R. Akylas, R. R. Rosales

See also 1.351, 1.541, 1.56J, 1.63, 1.691.

Engineering Systems, Economics, and Optimization

1.142[J] Robust Modeling, Optimization, and Computation
______

Graduate (Spring)
(Same subject as15.094[J])
Prereq: 18.06 or permission of instructor
Units: 4-0-8
______
Introduces modern robust optimization, including theory, applications, and computation. Presents formulations and their connection to probability, information and risk theory for conic optimization (linear, second-order, and semidefinite cones) and integer optimization. Application domains include analysis and optimization of stochastic networks, optimal mechanism design, network information theory, transportation, pattern classification, structural and engineering design, and financial engineering. Students formulate and solve a problem aligned with their interests in a final project.
D. Bertsimas

1.145[J] Engineering Economy Module
______

Graduate (Fall); partial term
(Same subject asIDS.331[J])
Prereq: None
Units: 1-0-2 [P/D/F]
Subject Cancelled Subject Cancelled
______
Presentation of the spreadsheet mechanics for the efficient calculation of discounted cash flows and related metrics of project worth; the use of data tables as means of exploring sensitivity analysis; and of simulation to develop the value of options. Intensive module designed for students who are not familiar with the efficient use of Excel. Presented intensively over first week of term.
R. de Neufville

1.146 Engineering Systems Analysis for Design
______

Graduate (Fall)
Engineering School-Wide Elective Subject.
(Offered under:1.146,16.861,IDS.332)
(Subject meets withIDS.333)
Prereq: 1.145 or permission of instructor
Units: 3-0-9
URL: http://msl1.mit.edu/mib/dsp/curricula.mit.edu/~dsplan/
Lecture: TR10.30-12 (1-390)
______
Covers theory and methods to identify, value, and implement flexibility in design, also known as "real options." Topics include definition of uncertainties, simulation of performance for scenarios, screening models to identify desirable flexibility, decision and lattice analysis, and multidimensional economic evaluation. Students demonstrate proficiency through an extended application to a systems design of their choice. Provides a complement to research or thesis projects. Meets with IDS.333 first half of term.
R. de Neufville
Textbooks (Fall 2016)

See also 1.202J, 1.203J, 1.283J, 1.731. For management of engineering systems, see also 1.040, 1.401J-1.482.


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Produced: 26-SEP-2016 05:10 PMFall 2016 Course 1: Civil and Environmental Engineering
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Course 1: Civil and Environmental Engineering
Fall 2016


Engineering Risk Assessment and Probabilistic Analysis

1.151 Probability and Statistics in Engineering
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces probability and statistics for engineering applications. Topics in probability include events and their probability, Total Probability and Bayes' Theorems, discrete and continuous random variables and vectors, Bernoulli Trial Sequence and Poisson point process, functions of random variables and vectors and conditional uncertainty analysis using full-distribution and second-moment uncertainty representation. Topics in statistics include estimation of distribution parameters, hypothesis testing, and simple linear regression. Concepts illustrated with examples from various areas of engineering and everyday life.
D. Veneziano

1.153 Transportation Policy, the Environment, and Livable Communities
______

Undergrad (Spring)
(Subject meets with1.253[J],11.543[J])
Prereq: 1.011
Units: 3-0-9
______
Examines the economic and political conflict between transportation and the environment. Investigates the role of government regulation, green business and transportation policy as a facilitator of economic development and environmental sustainability. Analyzes a variety of international policy problems, including government-business relations, the role of interest groups, non-governmental organizations, and the public and media in the regulation of the automobile; sustainable development; global warming; politics of risk and siting of transport facilities; environmental justice; equity; as well as transportation and public health in the urban metropolis. Provides students with an opportunity to apply transportation and planning methods to develop policy alternatives in the context of environmental politics. Students taking graduate version complete additional assignments.
J. Coughlin

See also 1.203J.

Transportation

1.200[J] Transportation Systems Analysis: Performance and Optimization
______

Graduate (Fall)
(Same subject as11.544[J])
Prereq: 1.010, permission of instructor
Units: 3-1-8
Lecture: TR10.30-12 (3-370) Recitation: R4 (3-370)
______
Problem-motivated introduction to methods, models and tools for the analysis and design of transportation networks including their planning, operations and control. Capacity of critical elements of transportation networks. Traffic flows and deterministic and probabilistic delay models. Formulation of optimization models for planning and scheduling of freight, transit and airline systems, and their solution using software packages. User- and system-optimal traffic assignment. Control of traffic flows on highways, urban grids, and airspace.
C. Osorio
No required or recommended textbooks

1.201[J] Transportation Systems Analysis: Demand and Economics
______

Graduate (Fall)
(Same subject as11.545[J])
Prereq: Permission of instructor
Units: 3-1-8
Lecture: TR2.30-4 (2-105) Recitation: F11 (2-105) +final
______
Covers the key principles governing transportation systems planning and management. Introduces the microeconomic concepts central to transportation systems. Topics include economic theories of the firm, consumer, and market, demand models, discrete choice analysis, cost models and production functions, and pricing theory. Applications to transportation systems - including congestion pricing, technological change, resource allocation, market structure and regulation, revenue forecasting, public and private transportation finance, and project evaluation - cover urban passenger transportation, freight, maritime, aviation, and intelligent transportation systems.
Staff
Textbooks (Fall 2016)

1.202 Demand Modeling
______

Graduate (Spring)
Prereq: 1.201 or permission of instructor
Units: 3-1-8
______
Theory and application of modeling and statistical methods for analysis and forecasting of demand for facilities, services, and products. Topics include: review of probability and statistics, estimation and testing of linear regression models, theory of individual choice behavior, derivation, estimation, and testing of discrete choice models (including logit, nested logit, GEV, probit, and mixture models), estimation under various sample designs and data collection methods (including revealed and stated preferences), sampling, aggregate forecasting methods, and iterative proportional fitting and related methods. Lectures reinforced with case studies, which require specification, estimation, testing, and analysis of models using data sets from actual applications.
Staff

1.203[J] Logistical and Transportation Planning Methods
______

Graduate (Spring)
(Same subject as15.073[J],16.76[J])
Prereq: 6.041B
Units: 3-0-9
______
Quantitative techniques of operations research with emphasis on applications in transportation systems analysis (urban, air, ocean, highway, and pickup and delivery systems) and in the planning and design of logistically oriented urban service systems (e.g., fire and police departments, emergency medical services, and emergency repair services). Unified study of functions of random variables, geometrical probability, multi-server queuing theory, spatial location theory, network analysis and graph theory, and relevant methods of simulation. Computer exercises and discussions of implementation difficulties.
R. C. Larson, A. I. Barnett

1.204 Computer Modeling: From Human Mobility to Transportation Networks
______

Graduate (Spring)
Prereq: 1.001, 1.010; or permission of instructor
Units: 3-0-9
______
Introduces methods for modeling individual travels at a country scale. Reviews basic concepts of data analysis, modeling, and visualization techniques. Topics include data mining to identify the structure inherent in daily behavior; introduction to fractals, random walks and methods to analyze trajectories. Algorithms to model and characterize complex networks, and their applications to daily commuting, air travels, and roads. Includes weekly open laptop exercises based on the data sets and methods from the research papers covered in class. Exposes students to the current challenges and opportunities in networks applied to human mobility.
M. C. Gonzalez

1.205 Advanced Demand Modeling
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 1.202 or permission of instructor
Units: 3-0-9
______
Advanced theories and applications of models for analysis and forecasting of users' behavior and demand for facilities, services, and products. Topics vary each year and typically include linear and nonlinear latent variable models, including structural equations and latent class models; estimation techniques with multiple data sources; joint discrete and continuous choice models; dynamic models; analysis of panel data; analysis of complex choices; estimation and forecasting with large choice sets; multidimensional probabilistic choice models; advanced choice models, including probit, logit mixtures, treatment of endogeneity, hybrid choice models, hidden Markov models, Monte Carlo simulation, Bayesian methods, survey design, sampling, model transferability, and use of stated preferences data. Term paper required.
M. E. Ben-Akiva

1.207 Computer Algorithms in Systems Engineering
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: 1.001 or permission of instructor
Units: 3-0-9
______
Covers concepts of computation in analysis of engineering systems. Data structures, relational database representations of engineering data. Algorithms for the solution and optimization of engineering system designs: greedy, dynamic programming, branch and bound, graph algorithms, nonlinear optimization. Provides an introduction to complexity analysis. Object-oriented, efficient implementations of algorithms.
Staff

1.208 Resilient Infrastructure Networks
______

Graduate (Fall)
Prereq: 1.151 or 6.431B; 15.093
Units: 3-0-9
Lecture: MW1-2.30 (5-233)
______
Control algorithms and game-theoretic tools to enable resilient operation of large-scale infrastructure networks. Dynamical network flow models, stability analysis, robust predictive control, fault and attack diagnostic tools. Strategic network design, routing games, congestion pricing, demand response, and incentive regulation. Design of operations management strategies for different reliability and security scenarios. Applications to transportation, logistics, electric-power, and water distribution networks.
S. Amin
No required or recommended textbooks

1.231[J] Planning and Design of Airport Systems
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as16.781[J],IDS.670[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (1-379)
______
Focuses on current practice, developing trends, and advanced concepts in airport design and planning. Considers economic, environmental, and other trade-offs related to airport location, as well as the impacts of emphasizing "green" measures. Includes an analysis of the effect of airline operations on airports. Topics include demand prediction, determination of airfield capacity, and estimation of levels of congestion; terminal design; the role of airports in the aviation and transportation system; access problems; optimal configuration of air transport networks and implications for airport development; and economics, financing, and institutional aspects. Special attention to international practice and developments.
R. de Neufville, A. R. Odoni
Textbooks (Fall 2016)

1.232[J] The Airline Industry
______

Graduate (Fall)
(Same subject as15.054[J],16.71[J])
Prereq: None
Units: 3-0-9
Lecture: MW1-2.30 (35-225)
______
Overview of the global airline industry, focusing on recent industry performance, current issues and challenges for the future. Fundamentals of airline industry structure, airline economics, operations planning, safety, labor relations, airports and air traffic control, marketing, and competitive strategies, with an emphasis on the interrelationships among major industry stakeholders. Recent research findings of the MIT Global Airline Industry Program are showcased, including the impacts of congestion and delays, evolution of information technologies, changing human resource management practices, and competitive effects of new entrant airlines. Taught by faculty participants of the Global Airline Industry Program.
P. P. Belobaba, A. I. Barnett, C. Barnhart, R. J. Hansman, T. A. Kochan
Textbooks (Fall 2016)

1.233[J] Air Transportation Operations Research
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as16.763[J])
Prereq: 16.71, 6.431, 15.093, or permission of instructor
Units: 3-0-9
______
Presents a unified view of advanced quantitative analysis and optimization techniques applied to the air transportation sector. Considers the problem of operating and managing the aviation sector from the perspectives of the system operators (e.g., the FAA), the airlines, and the resultant impacts on the end-users (the passengers). Explores models and optimization approaches to system-level problems, airline schedule planning problems, and airline management challenges. Term paper required.
H. Balakrishnan, C. Barnhart, P. P. Belobaba

1.234[J] Airline Management
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as16.75[J])
Prereq: 16.71J
Units: 3-0-9
______
Overview of airline management decision processes, with a focus on economic issues and their relationship to operations planning models and decision support tools. Application of economic models of demand, pricing, costs, and supply to airline markets and networks. Examination of industry practice and emerging methods for fleet planning, route network design, scheduling, pricing and revenue management, with emphasis on the interactions between the components of airline management and profit objectives in competitive environments. Students participate in a competitive airline management simulation game as part of the subject requirements.
P. P. Belobaba

1.251[J] Comparative Land Use and Transportation Planning
______

Graduate (Spring)
(Same subject as11.526[J])
Prereq: Permission of Instructor
Units: 3-0-9
______
Focuses on the integration of land use and transportation planning, drawing from cases in both industrialized and developing countries. Reviews underlying theories, analytical techniques, and the empirical evidence of the land use-transportation relationship at the metropolitan, intra-metropolitan, and micro-scales. Also covers the various ways of measuring urban structure, form, and the "built environment." Develops students' skills to assess relevant policies, interventions and impacts.
C. Zegras

1.252[J] Urban Transportation Planning
______

Graduate (Fall)
(Same subject as11.540[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: F2-5 (5-217)
______
Studies the history, policy, practice and politics of urban transportation. Covers the role of the federal, state, and local government and the MPO, public transit in the auto era, analysis of current trends and pattern breaks; analytical tools for transportation planning, traffic engineering and policy analysis; the contribution of transportation to air pollution, social costs and climate change; land use and transportation interactions; traffic and place making; bicycles, pedestrians, and traffic calming. Examples from the Boston area and from Bilbao.
F. Salvucci, M. Murga
No textbook information available

1.253[J] Transportation Policy, the Environment, and Livable Communities
______

Graduate (Spring)
(Same subject as11.543[J])
(Subject meets with1.153)
Prereq: Permission of instructor
Units: 3-0-9
______
Examines the economic and political conflict between transportation and the environment. Investigates the role of government regulation, green business and transportation policy as a facilitator of economic development and environmental sustainability. Analyzes a variety of international policy problems, including government-business relations, the role of interest groups, non-governmental organizations, and the public and media in the regulation of the automobile; sustainable development; global warming; politics of risk and siting of transport facilities; environmental justice; equity; as well as transportation and public health in the urban metropolis. Provides students with an opportunity to apply transportation and planning methods to develop policy alternatives in the context of environmental politics. Students taking graduate version complete additional assignments.
J. Coughlin

1.254 Transport Modeling Course
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Fosters practical experience with the concepts and approaches behind the analytical chain composed by GIS, 4-step planning, and traffic models. Study conducted in Greater Boston. Students develop road and street, pedestrian, and public transportation networks. Uses the latest Census Transportation Planning Products (CTPP) data, and Boston home travel survey to understand travel behavior and calibrate model. Final project involves the design of alternative futures for the metropolitan area with different transportation and land use policies.
Staff

1.258[J] Public Transportation Systems
______

Graduate (Spring)
(Same subject as11.541[J])
Prereq: 1.201 or permission of instructor
Units: 3-0-9
______
Discusses evolution and role of urban public transportation modes, systems and services, focusing on bus and rail. Describes technological characteristics and their impacts on capacity, service quality, and cost. Current practice and new methods for data collection and analysis, performance monitoring, route and network design, frequency determination, and vehicle and crew scheduling. Effect of pricing policy and service quality on ridership. Methods for estimating costs associated with proposed service changes. Organizational models for delivering public transportation service including finance and operations.
Staff

1.260[J] Logistics Systems
______

Graduate (Fall)
(Same subject as15.770[J],IDS.730[J],SCM.260[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: MW8.30-10 (E51-315)
______
Provides an introduction to supply chain management from both analytical and practical perspectives. Taking a unified approach, students develop a framework for making intelligent decisions within the supply chain. Covers key logistics functions, such as demand planning, procurement, inventory theory and control, transportation planning and execution, reverse logistics, and flexible contracting. Explores concepts such as postponement, portfolio management, and dual sourcing. Emphasizes skills necessary to recognize and manage risk, analyze various tradeoffs, and model logistics systems.
Y. Sheffi, C. Caplice
Textbooks (Fall 2016)

1.261[J] Case Studies in Logistics and Supply Chain Management
______

Graduate (Spring)
(Same subject as15.771[J],SCM.261[J])
Prereq: Permission of instructor
Units: 3-0-6
______
A combination of lectures and cases covering the strategic, management, and operating issues in contemporary logistics and integrated supply chain management. Includes: logistics strategy; supply chain restructuring and change management; and distribution, customer service, and inventory policy.
J. Byrnes

1.265[J] Global Supply Chain Management
______

Graduate (Spring)
(Same subject as2.965[J],15.765[J],SCM.265[J])
Prereq: 1.260, 1.261, 15.761, 15.778, or permission of instructor
Units: 2-0-4
______
Focuses on the planning, processes, and activities of supply chain management for companies involved in international commerce. Students examine the end-to-end processes and operational challenges in managing global supply chains, such as the basics of global trade, international transportation, duty, taxes, trade finance and hedging, currency issues, outsourcing, cultural differences, risks and security, and green supply chains issues. Highly interactive format features student-led discussions, staged debates, and a mock trial. Includes assignments on case studies and sourcing analysis, as well as projects and a final exam.
B. Arntzen

1.27 Studies in Transportation
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Individual advanced study of a topic in transportation systems, selected with the approval of the instructor.
Staff
No textbook information available

1.271[J] The Theory of Operations Management
______

Graduate (Spring) Can be repeated for credit
(Same subject as15.764[J],IDS.155[J])
Prereq: 15.081J or 6.251J, 6.436J; or permission of instructor
Units: 3-0-9
______
Provides mathematical foundations underlying the theory of operations management. Covers application domains, including inventory management, supply chain management and logistics, behavioral operations, healthcare management, service industries, pricing and revenue management, and auctions. Studies a wide range of mathematical and analytical techniques, such as dynamic programming, stochastic orders, behavioral and experimental economics, algorithms and approximations, data-driven and learning models, and mechanism design. Also provides hands-on experience in how to apply the theoretical models to solve OM problems in concrete business settings. Specific topics vary from year to year.
I. Ashlagi, D. Simchi-Levi, K. Zheng

1.273[J] Supply Chain Planning
______

Graduate (Spring)
(Same subject as15.762[J],IDS.150[J])
Prereq: 1.260 or 15.761
Units: 2-0-4
______
Focuses on effective supply chain strategies for companies that operate globally, with emphasis on how to plan and integrate supply chain components into a coordinated system. Students are exposed to concepts and models important in supply chain planning with emphasis on key tradeoffs and phenomena. Introduces and utilizes key tactics such as risk pooling and inventory placement, integrated planning and collaboration, and information sharing. Lectures, computer exercises, and case discussions introduce various models and methods for supply chain analysis and optimization. Recommended for Operations Management concentrators. First half-term subject.
Staff

1.274[J] Manufacturing System and Supply Chain Design
______

Graduate (Spring)
(Same subject as15.763[J],IDS.151[J])
Prereq: 1.260, 15.761, or 15.778
Units: 2-0-4
______
Focuses on decision making for system design, as it arises in manufacturing systems and supply chains. Students exposed to frameworks and models for structuring the key issues and trade-offs. Presents and discusses new opportunities, issues and concepts introduced by the internet and e-commerce. Introduces various models, methods and software tools for logistics network design, capacity planning and flexibility, make-buy, and integration with product development. Industry applications and cases illustrate concepts and challenges. Recommended for Operations Management concentrators. Second half-term subject.
S. C. Graves, D. Simchi-Levi

1.275[J] Business and Operations Analytics
______

Not offered academic year 2016-2017Graduate (Spring); first half of term
(Same subject asIDS.305[J])
Prereq: 1.145 or permission of instructor
Units: 2-0-4
______
Provides instruction on identifying, evaluating, and capturing business analytics opportunities that create value. Also provides basic instruction in analytics methods and case study analysis of organizations that successfully deployed these techniques.
D. Simchi-Levi

1.284[J] Analyzing and Accounting for Regional Economic Change
______

Graduate (Spring)
(Same subject as11.481[J])
Prereq: 14.03, 14.04
Units: 3-0-9
______
Surveys theories of regional growth, factor mobility, clustering, industrial restructuring, learning regions, and global supply chains from a political-economy perspective. Examines/critiques multipliers, linkages, and supply chains used to assess employment and environmental impacts, energy and infrastructure investments, and accounting issues related to the underground economy, work in the home, and environmental degradation. Assesses price indices, industrial location and employment measures, and shift-share analyses. Discussions of US and foreign applications.
Staff

1.285[J] Regional Socioeconomic Impact Analyses and Modeling
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as11.482[J])
Prereq: 11.481J or permission of instructor
Units: 2-1-9
URL: http://web.mit.edu/11.482/www/Syllabus482-2001.html
______
Reviews regional economic theories and models and provides students with experience in using alternative economic impact assessment models on microcomputers. Problem sets are oriented around infrastructure, housing, energy, and environmental issues. Students work with a client generally in Boston and make a presentation to the client. Emphasis on written and oral presentation skills.
K. R. Polenske

1.286[J] Urban Energy Systems and Policy
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as11.477[J])
(Subject meets with11.165)
Prereq: 11.203, 14.01, or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Examines efforts in developing and advanced nations and regions. Examines key issues in the current and future development of urban energy systems, such as technology, use, behavior, regulation, climate change, and lack of access or energy poverty. Case studies on a diverse sampling of cities explore how prospective technologies and policies can be implemented. Includes intensive group research projects, discussion, and debate.
D. Hsu

Geoenvironmental and Geotechnical Engineering

1.322 Soil Behavior
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 1.361
Units: 4-0-8
______
Detailed study of soil properties with emphasis on interpretation of field and laboratory test data and their use in soft-ground construction engineering. Includes: consolidation and secondary compression; basic strength principles; stress-strain strength behavior of clays, emphasizing effects of sample disturbance, anisotropy, and strain rate; strength and compression of granular soils; and engineering properties of compacted soils. Some knowledge of field and laboratory testing assumed; 1.37 desirable.
A. J. Whittle

1.331 Advanced Soil Dynamics
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: Permission of Instructor
Units: 3-0-9
______
Review of linear vibration theory for single- and multiple degree-of-freedom systems and for continuous systems. Propagation of waves in soils; soil amplification in vertically inhomogeneous media, including iterative method for inelastic media. Dynamic stiffness of foundations, vibration of machine foundations, effective motion of foundations for earthquake waves, inertial soil-structure interaction. Absorbing boundaries. Inelastic behavior of soils, non-linear response of soils under dynamic loads. Sliding block analysis, dynamic slope stability, liquefaction.
E. Kausel

1.34 Waste Containment and Remediation Technology
______

Graduate (Spring)
Prereq: 1.72 or permission of instructor
Units: 3-0-9
______
Hazardous waste site remediation and waste disposal facility design. Introduction to hazardous waste including definitions, US federal regulations, waste characteristics, environmental chemistry, hydrology, and contaminant transport. Characterization and remediation of contaminated sites, including preliminary site assessment, site investigation techniques, remediation technologies, risk assessment, and monitoring for soils, groundwater, and sediments. Design, construction, operation, and hydrology of waste disposal facilities.
Staff

1.351 Theoretical Soil Mechanics
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 1.361
Units: 3-0-9
______
Presentation of fundamental theories in soil mechanics: field equations of linear elasticity and solutions of boundary value problems. Introduction to finite element method. Steady and transient flow in porous media; applications in confined and unconfined seepage, and one-dimensional consolidation. Introduction to poro-elasticity. Yielding and failure of soils; plasticity theory and limit analyses, with examples for bearing capacity and slope stability. Cam Clay models and critical state theory of soil behavior.
A. J. Whittle

1.361 Advanced Soil Mechanics
______

Graduate (Fall); first half of term
(Subject meets with1.032)
Prereq: 1.036
Units: 3-0-6
Ends Oct 21. Lecture: TR10.30-12 (1-246) Recitation: W8.30 (1-371) +final
______
Covers topics in the characterization and nature of soils as multi-phase materials; the principle of effective stress; hydraulic conductivity and groundwater seepage; shear strength and stability analyses; stress-deformation properties, consolidatoin theory and calculation of settlements for clays and sands.
A. Whittle
No required or recommended textbooks

1.364 Advanced Geotechnical Engineering
______

Graduate (Fall); second half of term
Prereq: 1.361
Units: 3-0-6
Begins Oct 24. Lecture: TR10.30-12 (1-246) Recitation: W8.30 (1-371)
______
Methodology for site characterization and geotechnical aspects of the design and construction of foundation systems. Topics include site investigation (with emphasis on in situ testing), shallow (footings and raftings) and deep (piles and caissons) foundations, excavation support systems, groundwater control, slope stability, soil improvement (compaction, soil reinforcement, etc.), and construction monitoring.
A. Whittle
No required or recommended textbooks

1.37 Geotechnical Measurements and Exploration
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 1.035
Units: 3-4-2
______
Application of testing principles to the measurement of fundamental aspects of soil behavior from classification to engineering properties. Emphasis on rigorous techniques to measure mechanical behavior under various boundary conditions. Exposure to error estimation, research devices, geotechnical field exploration, andin situ testing. Extensive laboratory experiments to explore geotechnical test equipment and techniques. Laboratory use of testing automation and electronic instrumentation. Experiments include data analysis, evaluation, and presentation.
Staff

1.38 Engineering Geology
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-1-8
Lecture: TR9-10.30 (1-371) Lab: TBA
______
Studies the effect of geologic features and processes on constructed facilities; interaction between the geologic environment and man-made structures, and human activities in general. Planning of subsurface exploration. Engineering geologic characterization of soil and rock, including joint surveys and aspects of sedimented and residual soils. Laboratory on basic geologic identification and mapping techniques. Extensive reading of case histories. Field trip.
H. H. Einstein
Textbooks (Fall 2016)

1.381 Rock Mechanics
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 1.38, 1.361
Units: 3-0-9
______
Introduces theoretical and experimental aspects of rock mechanics and prepares students for rock engineering. Includes review of laboratory and field testing; empirical and analytical methods for describing strength, deformability and conductivity of intact rock and rock masses; fracture mechanics and mechanics of discontinua, including flow through discontinua and hydraulic fracturing; and design and analysis of rock slopes and foundations on rock. Also discusses blasting design. Includes term paper/term project.
H. H. Einstein

1.383 Underground Construction
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 1.361, 1.38, or permission of instructor
Units: 3-0-6
______
Provides familiarization with the most important aspects of planning, analysis, design, and construction of underground structures in soil and rock. Covers detailed engineering analysis and design, and major aspects of construction techniques and construction planning. Discusses general planning and economic problems. Includes a major design project involving all aspects of underground construction.
H. H. Einstein

1.39 Independent Study in Geotechnical Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
For graduate students desiring further individual study of topics in geotechnical engineering.
Information: A. J. Whittle
No textbook information available

Construction Engineering and Management

1.462[J] Entrepreneurship in Construction and Real Estate Development
______

Graduate (Fall); second half of term
(Same subject as11.345[J])
Prereq: Permission of instructor
Units: 2-0-4
Begins Oct 24. Lecture: R3-5.30 (9-354)
______
Develops skills necessary to incubate concepts for new real estate/built environment ventures and to evolve those ideas into viable startup ventures. Addresses the progression of an idea, from inception to opportunity to sustainable business. Students develop a business plan. Guest lecturers share their entrepreneurial paths and relevant experience. Explores the role of real estate developers in developing/emerging markets, with a focus on solving social development challenges, innovating new development strategies/products, and generating triple bottom-line returns with development projects.
J. F. Kennedy
Textbooks (Fall 2016)

1.463[J] Globalization and the Built Environment
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as11.342[J])
Prereq: Permission of instructor
Units: 2-0-4
______
Addresses the importance and pervasiveness of globalization in Architecture, Engineering and Construction Companies (AEC Firms). Covers strategies for a presence in the global market and the importance of the global financial market in project financing, with a primary focus on infrastructure. Includes discussion of innovative approaches to marketing, partnering, risk management, finance, specialized delivery systems, and privatization.
F. Moavenzadeh, D. Wolff

1.472[J] Innovative Project Delivery in the Public and Private Sectors
______

Graduate (Spring); first half of term
(Same subject as11.344[J])
Prereq: Permission of instructor
Units: 2-0-4
______
Develops a strong strategic understanding of how best to deliver various types of projects in the built environment. Examines the compatibility of various project delivery methods, consisting of organizations, contracts, and award methods, with certain types of projects and owners. Six methods examined: traditional general contracting; construction management; multiple primes; design-build; turnkey; and build-operate-transfer. Includes lectures, case studies, guest speakers, and a team project to analyze a case example.
C. M. Gordon


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Produced: 26-SEP-2016 05:10 PMFall 2016 Course 1: Civil and Environmental Engineering
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Course 1: Civil and Environmental Engineering
Fall 2016


Materials and Structures

1.541 Mechanics and Design of Concrete Structures
______

Graduate (Fall)
(Subject meets with1.054)
Prereq: 1.035
Units: 3-0-9
Lecture: MW1-2.30 (1-246)
______
Studies strength and deformation of concrete under various states of stress; failure criteria; concrete plasticity; and fracture mechanics concepts. Topics include fundamental behavior of reinforced concrete structural systems and their members; basis for design and code constraints; high-performance concrete materials and their use in innovative design solutions; and yield line theory for slabs. Uses behavior models and nonlinear analysis. Covers complex systems, including bridge structures, concrete shells, and containments. Students taking graduate version complete additional assignments.
O. Buyukozturk
Textbooks (Fall 2016)

1.545 Atomistic Modeling and Simulation of Materials and Structures
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Covers multiscale atomistic modeling and simulation methods, with focus on mechanical properties (elasticity, plasticity, creep, fracture, fatigue) of a range of materials (metals, ceramics, proteins, biological materials, biomaterials). Topics include mechanics of materials (energy principles, nano-/micromechanics, deformation mechanisms, size effects, hierarchical biological structures) and atomistic modeling (chemistry, interatomic potentials, visualization, data analysis, numerical methods, supercomputing, algorithms). Includes an interactive computational project.
M. J. Buehler

1.546 Statistical Mechanics of Biological Systems
______

Not offered academic year 2016-2017Graduate (IAP)
Prereq: Permission of instructor
Units: 2-0-4
______
Develops the theory and methods of statistical mechanics of biological systems specifically relevant to environmental engineers. Intended for students with a background in biology, but without prior exposure to statistical mechanics.
E. Alm

1.56[J] Structural Mechanics in Nuclear Power Technology
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as2.084[J],22.314[J])
Prereq: 2.001 or permission of instructor
Units: 3-0-9
______
Structural components in nuclear power plant systems, their functional purposes, operating conditions, and mechanical/structural design requirements. Combines mechanics techniques with models of material behavior to determine adequacy of component design. Considerations include mechanical loading, brittle fracture, inelastic behavior, elevated temperatures, neutron irradiation, vibrations and seismic effects.
Staff

1.561 Motion-Based Design
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Presents a rational basis for the preliminary design of motion-sensitive structures. Topics include: analytical and numerical techniques for establishing the optimal stiffness distribution, the role of damping in controlling motion, tuned mass dampers, base isolation systems, and an introduction to active structural control. Examples illustrating the application of the motion-based design paradigm to building structures subjected to wind and seismic excitation are discussed.
Staff

1.562 Structural Design Project I
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Lecture: F2-5 (1-371)
______
Students work in teams to design a long-span structure, emphasizing conceptual design and advanced structural analysis. Subject covers structural systems and construction methods, interdisciplinary collaboration, design strategies for resistance to static and dynamic loading, and simplified calculation methods to validate numerical simulations. Emphasis on oral and visual communication of engineering concepts and students present their projects to leading engineers for feedback.
J. Ochsendorf, G. Herning
No textbook information available

1.563 Structural Design Project II
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Students work in teams to design a tall building, emphasizing the design of vertical load systems, lateral load systems, and floor systems. Uses studies of precedent buildings and metrics of structural performance including material efficiency and embodied carbon to evaluate multiple design concepts. Simplified calculation methods are validated with advanced numerical simulations. Formal presentations will be used to improve oral and visual communication.
J. Ochsendorf

1.57 Mechanics of Materials: An Energy Approach
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 1.050 or permission of instructor
Units: 3-2-7
______
An opportunity to update knowledge in continuum mechanics and constitutive behavior, and modeling of engineering materials based on thermodynamics of irreversible processes. Introduction to continuum mechanics and material modeling of engineering materials based on first energy principles: deformation and strain; momentum balance, stress, and stress states; elasticity and elasticity bounds; plasticity and yield design. Overarching theme is a unified mechanistic language using thermodynamics, which allows for understanding, modeling, and design of a broad range of engineering materials.
F. J. Ulm

1.570 Micromechanics and Durability of Solids
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 1.050, 1.57; or permission of instructor
Units: 3-0-9
______
Introduction to fracture mechanics, poromechanics and micromechanics using a unified mechanistic approach based on energy principles for modeling a large range of man-made and natural engineering material behavior. Energy release and fracture energy, stress intensity factors and toughness, saturated and partially saturated poromechanics of deformable porous materials, Darcy's law, linear micromechanics and application to porous materials, homogenization methods, chemomechanics of dissolution processes. In addition to assignments, emphasizes development of a consistent engineering science approach, culminating in a term paper.
F. J. Ulm

1.571 Modeling and Analysis of Structures
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Covers analytical and computer-based methods for the analysis of structural systems. Introduces strategies for the quantitative study of indeterminate and nonlinear structures. Topics provide insight into structural analysis software and the implementation of the finite element method. Emphasizes modeling complex structural behavior, such as elastic instability, local and global buckling, physical nonlinearity, geometric stiffness, and thermal expansion. Application examples cover a range of structural components and systems, with models and methods specific to the study of building frames, arches, shells, and cable-supported and tensile structures. Assignments provide experience with the construction of mathematical and finite element models, the derivation of closed-form solutions, and the effective use of structural analysis programs.
Staff

1.572 Structural Systems
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Designed to complement general structural analysis classes. Provides an understanding of the full range of structures and structural forms, including how they are designed and built. Develops skills necessary for conceptual design work, such as how to visualize options and judge their relative advantages in a qualitative manner. Case studies demonstrate how to conceive a structural form and consider its various options, and to understand assembly and construction methods intrinsic to the real behavior of the final structure.
Staff

1.573[J] Structural Mechanics
______

Graduate (Fall)
(Same subject as2.080[J])
Prereq: 2.002
Units: 4-0-8
URL: http://deslab.mit.edu/DesignLab/courses/13.10/1310.html
Lecture: MW2.30-4 (2-105) Recitation: F9 (3-442)
______
Presents fundamental concepts of structural mechanics with applications to marine, civil, and mechanical structures. Covers residual stresses; thermal effects; analysis of beams, columns, tensioned beams, trusses, frames, arches, cables, and shafts of general shape and material, including composites; elastic buckling of columns; exact and approximate methods, energy methods, principle of virtual work, and introduction to computational structural mechanics.
T. Wierzbicki, H. Schmidt
Textbooks (Fall 2016)

1.574[J] Analysis of Historic Structures
______

Graduate (Fall)
(Same subject as4.445[J])
(Subject meets with4.444)
Prereq: None
Units: 3-0-6
URL: http://architecture.mit.edu/subject/fall-2016-4444
Lecture: W2-5 (1-242)
______
Technical and historical study of structures in architecture and engineering. Focuses on the design and assessment of historic structures in masonry, timber, concrete, and metal. Course is driven by student research proposals. Previous student projects have researched Gothic flying buttresses, wooden covered bridges, Roman aqueducts, and iron train stations.
J. Ochsendorf
Textbooks (Fall 2016)

1.575[J] Computational Structural Design and Optimization
(New)
______

Graduate (Fall)
(Same subject as4.450[J])
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4450
Lecture: F9-12 (9-354) +final
______
Research seminar focusing on cutting-edge applications of computation for creative, early-stage structural design and optimization for architecture. Incorporates computational design fundamentals, including problem parameterization and formulation; design space exploration strategies, including interactive, heuristic, and gradient-based optimization; and computational structural analysis methods, including the finite element method, graphic statics, and approximation techniques. Case studies introduce and investigate a range of historical and contemporary examples of structural optimization in theory and practice.
C. Mueller
No textbook information available

1.581[J] Structural Dynamics and Vibrations
______

Graduate (Fall)
(Same subject as2.060[J],16.221[J])
(Subject meets with1.058)
Prereq: Permission of instructor
Units: 3-1-8
Lecture: MWF10 (1-390) Recitation: W4 (1-246)
______
Single- and multiple-degree-of-freedom vibration problems, using matrix formulation and normal mode superposition methods. Time and frequency domain solution techniques including convolution and Fourier transforms. Applications to vibration isolation, damping treatment, and dynamic absorbers. Analysis of continuous systems by exact and approximate methods. Applications to buildings, ships, aircraft and offshore structures. Vibration measurement and analysis techniques. Students should possess basic knowledge in structural mechanics and in linear algebra. Students taking graduate version complete additional assignments.
E. Kausel, J. K. Vandiver
No textbook information available

1.582 Design of Steel Structures
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Lecture: TR9.30-11 (1-379)
______
Provides ability to design and assess steel structures. Steel structures are taught at three levels: the overall structural system (multi-story buildings, wide-span buildings, bridges, masts, and towers); the components of a structural system (floor systems, plate girders, frames, and beams); and the details of structural components (connection types, welding, and bolting). Each level includes a balance among theoretical analysis, design requirements, and construction/cost considerations. Existing structures are used as worked examples.
J. Ochsendorf, G. Herning
Textbooks (Fall 2016)

1.589 Studies in Structural Design and Analysis
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Individual study of advanced subjects under staff supervision. Content arranged to suit the particular requirements of the student and interested members of the staff.
Information: O. Buyukozturk
No textbook information available

1.597 Studies in Construction Materials
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Advanced topics in construction materials selected by students for individual study with staff approval.
Information: O. Buyukozturk
No textbook information available

Hydrodynamics and Coastal Engineering

1.61 Transport Processes in the Environment
______

Graduate (Fall)
(Subject meets with1.061)
Prereq: 1.060B
Units: 3-1-8
Lecture: MWF10 (48-316) Recitation: F11 (48-316) +final
______
Introduces mass transport in environmental flows, with emphasis on river and lake systems. Covers derivation and solutions to the differential form of mass conservation equations. Topics include molecular and turbulent diffusion, boundary layers, dissolution, bed-water exchange, air-water exchange, and particle transport. Meets with 1.061A first half of term. Students taking graduate version complete additional assignments.
H. M. Nepf
No required or recommended textbooks

1.63[J] Advanced Fluid Dynamics
______

Graduate (Spring)
(Same subject as2.26[J])
Prereq: 18.085; 2.25 or permission of instructor.
Units: 4-0-8
URL: http://web.mit.edu/1.63/www/lecnote.html
______
Fundamentals of fluid dynamics intrinsic to natural physical phenomena and/or engineering processes. Discusses a range of topics and advanced problem-solving techniques. Sample topics include brief review of basic laws of fluid motion, scaling and approximations, creeping flows, boundary layers in high-speed flows, steady and transient, similarity method of solution, buoyancy-driven convection in porous media, dispersion in steady or oscillatory flows, physics and mathematics of linearized instability, effects of shear and stratification. In alternate years, two of the following modules will be offered: I: Geophysical Fluid Dynamics of Coastal Waters, II: Capillary Phenomena, III: Non-Newtonian Fluids, IV: Flagellar Swimming.
T. R. Akylas, G. H. McKinley, R. Stocker

1.631[J] Fluid Dynamics and Disease
______

Graduate (Spring)
(Same subject asHST.537[J])
Prereq: None
Units: 3-0-9
______
Reviews theoretical notions in mathematical epidemiology and open problems in understanding and modeling disease onset and spread. Bridges the disease modeling efforts at the large-scale population-level and those at the micro-scale pathogen-level via the use of fluid dynamics. Covers topics such as interfacial flows, fluid fragmentation, multiphase flows, turbulent flows, and fluid-structure interaction. Intended for students with a strong quantitative background interested in learning about applications in health and epidemiology and for students with an epidemiology and health background interested in learning about fluid dynamics approaches relevant to disease transmission. In the spirit of the OneHealth Initiative, covers advanced topics on the health of human, animal, and plant populations.
L. Bourouiba

1.64 Physical Limnology
______

Graduate (Spring)
Not offered regularly; consult department
(Subject meets with1.064)
Prereq: 1.061
Units: 3-0-9
______
Provides an introduction to physical processes occurring in lakes and shallow surface water systems with emphasis on mechanisms affecting fate and transport. Topics include internal waves, differential heating and cooling, boundary mixing, turbulent mixing, and influence of vegetation. Begins with a review of Navier-Stokes equation. Students taking graduate version complete additional assignments.
H. M. Nepf

1.66 Problems in Water Resources and Environmental Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Individual study in advanced topics as arranged between individual students and staff. Choice of subjects from theoretical, experimental, and practical phases of hydromechanics, hydraulic engineering, water resources, hydrology, and environmental engineering.
Staff
No textbook information available

1.67 Sediment Transport and Coastal Processes
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 1.061
Units: 4-0-8
______
Emphasizes the quantitative description of the mechanics of sediment transport in steady and unsteady flows based on hydrodynamic principles. Equations of motion for particles in a turbulent flow, entrainment, bedload, and suspended load. Bedform mechanics, ripples, and dunes. Flow resistance and boundary-layer mechanics for waves and combined wave-current flows. Wave-induced longshore currents, longshore and on-offshore sediment transport. Coastal protection.
Staff

1.685[J] Nonlinear Dynamics and Waves
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as2.034[J],18.377[J])
Prereq: Permission of instructor
Units: 3-0-9
______
A unified treatment of nonlinear oscillations and wave phenomena with applications to mechanical, optical, geophysical, fluid, electrical and flow-structure interaction problems. Nonlinear free and forced vibrations; nonlinear resonances; self-excited oscillations; lock-in phenomena. Nonlinear dispersive and nondispersive waves; resonant wave interactions; propagation of wave pulses and nonlinear Schrodinger equation. Nonlinear long waves and breaking; theory of characteristics; the Korteweg-de Vries equation; solitons and solitary wave interactions. Stability of shear flows. Some topics and applications may vary from year to year.
T. R. Akylas, R. R. Rosales

1.686[J] Nonlinear Dynamics and Turbulence
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as18.358[J])
(Subject meets with1.068)
Prereq: 18.355 or permission of instructor
Units: 3-0-9
______
Reviews theoretical notions of nonlinear dynamics, instabilities, and waves with applications in fluid dynamics. Discusses hydrodynamic instabilities leading to flow destabilization and transition to turbulence. Focuses on physical turbulence and mixing from homogenous isotropic turbulence. Also covers topics such as rotating and stratified flows as they arise in the environment, wave-turbulence, and point source turbulent flows. Students taking graduate version complete additional assignments.
L. Bourouiba

1.69 Introduction to Coastal Engineering
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 1.061
Units: 4-0-8
______
Basic dynamics of ocean surface waves; wave-driven, wind-driven, and tidal currents; boundary layers and sediment transport; and selected engineering applications. Formulation of the boundary-value problem for surface waves, linear plane-wave solution, shoaling, refraction, diffraction, statistical representation, and elements of nonlinearity. Depth-averaged formulation and selected solutions for sea level and currents driven by waves, winds, and tides. Elements of boundary layers, initial sediment motion, and bedload and suspended sediment transport. Alongshore sediment transport and shoreline change. Emphasizes basic principles, mathematical formulation and solution, and physical interpretation, with selected applications and exposure to current research.
J. Trowbridge

1.692[J] Ocean Wave Interaction with Ships and Offshore Energy Systems
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as2.24[J])
Prereq: 2.20, 18.085
Units: 4-0-8
______
Surface wave theory, conservation laws and boundary conditions, properties of regular surface waves and random ocean waves. Linearized theory of floating body dynamics, kinematic and dynamic free surface conditions, body boundary conditions. Simple harmonic motions. Diffraction and radiation problems, added mass and damping matrices. General reciprocity identities on diffraction and radiation. Ship wave resistance theory, Kelvin wake physics, ship seakeeping in regular and random waves. Discusses point wave energy absorbers, beam sea and head-sea devises, oscillating water column device and Well's turbine. Discusses offshore floating energy systems and their interaction with ambient waves, current and wind, including oil and gas platforms, liquefied natural gas (LNG) vessels and floating wind turbines. Homework drawn from real-world applications.
P. D. Sclavounos

1.699[J] Projects in Oceanographic Engineering
______

Graduate (Fall, Summer) Can be repeated for credit
(Same subject as2.689[J])
Prereq: Permission of instructor
Units arranged [P/D/F]
Meets at WHOI. TBA.
______
Projects in oceanographic engineering, carried out under supervision of Woods Hole Oceanographic Institution staff. Given at Woods Hole Oceanographic Institution.
J. Preisig, Woods Hole Staff
No textbook information available

Hydrology and Water Resource Systems

1.714 Surface Hydrology
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 1.070B or permission of instructor
Units: 3-0-9
______
Covers observations and theory of the physical processes involved in the hydrologic cycle. Processes considered are rainfall, infiltration, runoff generation, stream flow, evaporation, transpiration,and rainfall interception.
E. A. B. Eltahir

1.72 Groundwater Hydrology
______

Graduate (Fall)
(Subject meets with1.072)
Prereq: 1.061
Units: 3-1-8
Lecture: MW2.30-4 (48-308) Recitation: TBA +final
______
Presents the fundamentals of subsurface flow and transport, emphasizing the role of groundwater in the hydrologic cycle, the relation of groundwater flow to geologic structure, and the management of contaminated groundwater. Topics include Darcy equation, flow nets, mass conservation, the aquifer flow equation, heterogeneity and anisotropy, storage properties, regional circulation, unsaturated flow, recharge, stream-aquifer interaction, well hydraulics, flow through fractured rock, numerical models, groundwater quality, contaminant transport processes, dispersion, decay, and adsorption. Includes laboratory and computer demonstrations. Students taking graduate version complete additional assignments.
C. Harvey
No textbook information available

1.721 Advanced Subsurface Hydrology
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 1.72, 18.075, permission of instructor
Units: 3-0-9
______
Advanced treatment of solute transport in natural porous media with a focus on coupled chemical reaction and transport. Numerical modeling. Stochastic treatment of temporal and spatial variability. Mobile/immobile domain mass transfer, macrodispersion, tracer tests, salt water intrusion, heat transport.
C. Harvey

1.723 Computational Methods for Flow in Porous Media
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Covers physical, mathematical and simulation aspects of fluid flow and transport through porous media. Conservation equations for multiphase, multicomponent flow. Upscaling of parameters in heterogeneous fields. Modeling of viscous fingering and channeling. Numerical methods for elliptic equations: finite volume methods, multipoint flux approximations, mixed finite element methods, variational multiscale methods. Numerical methods for hyperbolic equations: low-order and high-order finite volume methods, streamline/front-tracking methods. Applications to groundwater contamination, oil and gas reservoir simulation, and geological CO2 sequestration, among others. Limited to graduate students.
R. Juanes

1.725 Chemicals in the Environment: Fate and Transport
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
______
For Institute students in all departments interested in the behavior of chemicals in the environment. Subject covers the movement of chemicals through water, air, and soil, and also addresses their eventual fate. Physical transport, as well as chemical and biological sources and sinks, are discussed. Emphasis on anthropogenic chemicals, though in the context of pre-existing natural chemical cycles. Linkages to health effects, sources and control, and policy aspects. Core requirement for Environmental MEng program.
H. Hemond

1.731 Water Resource Systems
______

Graduate (Fall)
(Subject meets with1.075)
Prereq: 1.070B or permission of instructor
Units: 3-0-9
Lecture: TR2.30-4 (48-316) +final
______
Surveys optimization and simulation methods for management of water resources. Case studies illustrate linear, quadratic, nonlinear programming and real-time control. Applications include river basin planning, irrigation and agriculture, reservoir operations, capacity expansion, assimilation of remote sensing data, and sustainable resource development. Students taking graduate version complete additional assignments.
D. McLaughlin
No textbook information available

1.74 Land, Water, Food, and Climate
______

Graduate (Spring)
Prereq: None
Units: 3-0-3
______
Seminar examines food production in a changing world, with an emphasis on key scientific questions about the connections between natural resources, climate, and agriculture. Students read and discuss papers on a range of topics, including water and land resources, climate change, demography, agro-ecology, biotechnology, trade, and food security. Provides a broad and balanced perspective on one of the defining global issues of this century. Considers scientific controversies as well as areas of general agreement and examines practical solutions for addressing critical problems. Participants present reviews of selected papers and lead follow-up discussions. They also have a role in shaping subject content.
D. McLaughlin

Aquatic Sciences, Water Quality Control, and Environmental Management

1.75 Limnology and Wetland Ecology
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Examines the major physical, chemical, and biological features of lakes and wetlands: basin geology, water budget, heat balance, thermal stratification, lake circulation, energy flow, biological communities, and cycles of major elements. Explores methodologies of limnology, including field methods and use of models, applications of modern sensor technology to lake and wetland studies and current issues in lake and wetland management.
H. F. Hemond

1.76 Aquatic Chemistry
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Chemistry (GIR) or 5.60
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Quantitative treatment of chemical processes in aquatic systems such as lakes, oceans, rivers, estuaries, groundwaters, and wastewaters. A brief review of chemical thermodynamics is followed by discussion of acid-base, precipitation-dissolution, coordination, and reduction-oxidation reactions. Emphasis is on equilibrium calculations as a tool for understanding the variables that govern the chemical composition of aquatic systems and the fate of inorganic pollutants.
B. Kocar

1.77 Water Quality Control
______

Graduate (Spring)
Prereq: 1.060B
Units: 3-0-9
______
Emphasizes mathematical models for predicting distribution and fate of effluents discharged into lakes, reservoirs, rivers, estuaries, and oceans. Focuses on formulation and structure of models as well as analytical and simple numerical solution techniques. Role of element cycles, such as oxygen, nitrogen, and phosphorus, as water quality indicators. Offshore outfalls and diffusion. Salinity intrusion in estuaries. Thermal stratification, eutrophication, and sedimentation processes in lakes and reservoirs.
E. E. Adams

1.78 Introduction to Soil Science
(New)
______

Graduate (Fall)
(Subject meets with1.078)
Prereq: None
Units: 3-1-8
Lecture: TR1-2.30 (48-308) Recitation: R4 (48-109) +final
______
Presents the physical, chemical, biological and genetic properties of soils, their global distribution, and response to management. Emphasizes factors controlling soil development, plant productivity, and the fate, cycling and bioavailability of soil nutrients and pollutants. Introduces Earth's different soil types and their classification; links characteristics with contemporary and historic issues surrounding natural and managed soil systems. Topics include soil carbon cycling, water and fertilizer management, and challenges associated with soil salinity-sodicity, erosion, and pollution. Includes field trips to local sites to examine soil physical properties, classification, and function. Introductory biology and chemistry are recommended prerequisites. Students taking graduate version complete additional assignments.
B. Kocar
Textbooks (Fall 2016)

1.801[J] Environmental Law, Policy, and Economics: Pollution Prevention and Control
______

Undergrad (Fall) HASS Social Sciences
(Same subject as11.021[J],17.393[J])
(Subject meets with1.811[J],11.630[J],IDS.430[J])
Prereq: None
Units: 3-0-9
Credit cannot also be received for15.663
Lecture: TR3.30-5 (E51-057) +final
______
Introduction to important issues in contemporary environmental law, policy, and economics. Discusses the roles and interactions of Congress, federal agencies, state governments, and the courts in dealing with environmental problems. Topics include common law, administrative law, environmental impact assessments required by the National Environmental Policy Act, and legislation and court decisions dealing with air pollution, water pollution, the control of hazardous waste, pollution and accident prevention, the production and use of toxic chemicals, community right-to-know, and environmental justice. Explores the role of science and economics in legal decisions, and economic incentives as an alternative or supplement to regulation. Analyzes pollution as an economic problem and a failure of markets. Introduction to basic legal skills: how to read and understand cases, regulation, and statutes; how to discover the current state of the law in a specific area; and how to take action toward resolution of environmental problems. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C. Caldart
Textbooks (Fall 2016)

1.802[J] Regulation of Chemicals, Radiation, and Biotechnology
______

Undergrad (Spring)
Not offered regularly; consult department
(Same subject as11.022[J])
(Subject meets with1.812[J],10.805[J],11.631[J],IDS.431[J],IDS.436[J])
Prereq: 1.801 or permission of instructor
Units: 3-0-9
______
Focuses on policy design and evaluation in the regulation of hazardous substances and processes. Includes risk assessment, industrial chemicals, pesticides, food contaminants, pharmaceuticals, radiation and radioactive wastes, product safety, workplace hazards, indoor air pollution, biotechnology, victims' compensation, and administrative law. Health and economic consequences of regulation, as well as its potential to spur technological change, are discussed for each regulatory regime. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C. Caldart

1.811[J] Environmental Law, Policy, and Economics: Pollution Prevention and Control
______

Graduate (Fall)
(Same subject as11.630[J],IDS.430[J])
(Subject meets with1.801[J],11.021[J],17.393[J])
Prereq: Permission of instructor for undergraduates
Units: 3-0-9
Credit cannot also be received for15.663
Lecture: TR3.30-5 (E51-057) +final
______
Reviews and analyzes federal and state regulation of air and water pollution, hazardous wastes, and the production and use of toxic chemicals. Analyzes pollution as an economic problem and the failure of markets. Emphasizes use of legal mechanisms and alternative approaches (such as economic incentives and voluntary approaches) to control pollution and to encourage chemical accident and pollution prevention. Focuses on the major federal legislation, the underlying administrative system, and the common law in analyzing environmental policy, economic consequences, and the role of the courts. Discusses classical pollutants and toxic industrial chemicals, community right-to-know, and environmental justice. Also provides an introduction to basic legal skills. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C. Caldart
Textbooks (Fall 2016)

1.812[J] Regulation of Chemicals, Radiation, and Biotechnology
______

Graduate (Spring)
Not offered regularly; consult department
(Same subject as11.631[J],IDS.431[J])
(Subject meets with1.802[J],10.805[J],11.022[J],IDS.436[J])
Prereq: 1.811 or permission of instructor
Units: 3-0-9
______
Focuses on policy design and evaluation in the regulation of hazardous substances and processes. Includes risk assessment, industrial chemicals, pesticides, food contaminants, pharmaceuticals, radiation and radioactive wastes, product safety, workplace hazards, indoor air pollution, biotechnology, victims' compensation, and administrative law. Health and economic consequences of regulation, as well as its potential to spur technological change, are discussed for each regulator regime. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C.Caldart

1.813[J] Technology, Globalization, and Sustainable Development
______

Graduate (Fall)
(Same subject as11.466[J],15.657[J],IDS.437[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: W EVE (4-6.30 PM) (E51-376)
______
Investigates sustainable development, taking a broad view to include not only a healthy economic base, but also a sound environment, stable employment, adequate purchasing power, distributional equity, national self-reliance, and maintenance of cultural integrity. Explores national, multinational, and international political and legal mechanisms to further sustainable development through transformation of the industrial state. Addresses the importance of technological innovation and the financial crisis of 2008.
N. Ashford
Textbooks (Fall 2016)

1.818[J] Sustainable Energy
______

Graduate (Fall)
(Same subject as2.65[J],10.391[J],11.371[J],22.811[J])
(Subject meets with2.650[J],10.291[J],22.081[J])
Prereq: Permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/10.391J/www/
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various energy technologies in each fuel cycle stage for fossil (oil, gas, synthetic), nuclear (fission and fusion) and renewable (solar, biomass, wind, hydro, and geothermal) energy types, along with storage, transmission, and conservation issues. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments.
M. W. Golay
Textbooks (Fall 2016)

1.819[J] Design for Sustainability
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as4.447[J])
Prereq: Permission of instructor
Units: 2-0-4
Subject Cancelled Subject Cancelled
______
Presents thought processes and quantitative tools, including life-cycle assessment (LCA) and the LEED and ENVSION rating systems, applicable to integrated design of buildings and horizontal infrastructure with the goal of minimizing the waste of materials, energy, and water. Readings, lectures, site visits, and assignments encourage systematic thinking and interdisciplinary collaboration to make sustainable design a reality. Includes a team project of students' choice, such as a conceptual design of a sustainable new building, a "green" retrofit, or a comparative LCA.
J. Ochsendorf

1.83 Environmental Organic Chemistry
______

Graduate (Fall)
(Subject meets with1.831)
Prereq: 5.60, 18.03
Units: 4-0-8
Lecture: MW1-2.30 (48-316) Recitation: F1 (48-316) +final
______
Focuses on the processes affecting organic compounds in the environment. Uses physical chemical properties to predict chemical transfers between environmental compartments (air, water, sediments, and biota). Uses molecular structure-reactivity relationships to estimate chemical, photochemical, and biochemical transformation rates. Resulting process models are combined to predict environmental concentrations (and related biological exposures) of anthropogenic and natural organic compounds.
P. M. Gschwend
No required or recommended textbooks

1.831 Environmental Organic Chemistry
______

Graduate (Fall)
(Subject meets with1.83)
Prereq: 5.60, 18.03
Units: 4-0-8
Lecture: MW1-2.30 (48-316) Recitation: F1 (48-316) +final
______
Focuses on the processes affecting organic compounds in the environment. Uses physical chemical properties to predict chemical transfers between environmental compartments (air, water, sediments, and biota). Uses molecular properties to estimate chemical, photochemical, and biochemical transformation rates. Resulting process models are combined to predict environmental concentrations (and related biological exposures) of anthropogenic and natural organic compounds.
P. M. Gschwend
No textbook information available

1.84[J] Atmospheric Chemistry
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as 10.817[J],12.807[J])
Prereq: 5.60
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Provides a detailed overview of the chemical transformations that control the abundances of key trace species in the Earth's atmosphere. Emphasizes the effects of human activity on air quality and climate. Topics include photochemistry, kinetics, and thermodynamics important to the chemistry of the atmosphere; stratospheric ozone depletion; oxidation chemistry of the troposphere; photochemical smog; aerosol chemistry; and sources and sinks of greenhouse gases and other climate forcers.
J. H. Kroll

1.841[J] Atmospheric Composition in the Changing Earth System
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as12.817[J])
Prereq: 1.84
Units: 3-0-9
______
Explores how atmospheric chemical composition both drives and responds to climate, with a particular focus on feedbacks via the biosphere. Topics include atmospheric nitrogen; DMS, sulfate, and CLAW; biogenic volatile organic compounds and secondary organic aerosol; wildfires and land use change; atmospheric methane and the oxidative capacity of the troposphere; and air quality and climate and geoengineering.
C. Heald

1.842[J] Aerosol and Cloud Microphysics and Chemistry
______

Graduate (Spring)
(Same subject as12.814[J])
(Subject meets with12.338)
Prereq: Permission of instructor
Units: 3-0-9
______
Focuses on understanding how aerosol particles form droplets or ice crystals during several atmospheric processes: determining Earth's radiative balance; heterogeneous chemistry and acid rain; understanding where, when and how much precipitation occurs. Provides tools for understanding the physics of aerosol and cloud element motion; the interaction of particles with water vapor, including phase changes and droplet and ice nucleation; the chemical composition of particles and the effect on cloud formation processes; and the effect of cloud processing on aerosol chemistry. Discusses relevant topics of contemporary interest, e.g., geoengineering and weather modification and volcanic effects. Students taking the graduate version complete different assignments.
D. Cziczo

1.851[J] Water, Sanitation, Hygiene and Environmental Sanitation (WASH-ENV) in Low- and Middle-income Countries
______

Graduate (Spring)
(Same subject as11.479[J])
Prereq: None
Units arranged
______
Addresses principles and practice of water, sanitation, hygiene and environmental sanitation (WASH-ENV) systems, infrastructure, engineering, and planning in low- and middle-income countries. Incorporates interdisciplinary technical, socio-cultural, public health, human rights, behavioral, and economic aspects into the design and implementation of interventions. Students develop skills to plan simple, yet reliable, WASH-ENV systems together with urban or rural communities that are compatible with local customs and available human and material resources.
Staff

1.86[J] Methods and Problems in Microbiology
______

Graduate (Fall)
(Same subject as7.492[J],20.445[J])
Prereq: None
Units: 3-0-9
Lecture: W EVE (3-6 PM) (4-146)
______
Students will read and discuss primary literature covering key areas of microbial research with emphasis on methods and approaches used to understand and manipulate microbes. Preference to first-year Microbiology and Biology students.
M. Laub
No required or recommended textbooks

1.87[J] Microbial Genetics and Evolution
______

Graduate (Fall)
(Same subject as7.493[J],12.493[J],20.446[J])
Prereq: 7.03, 7.05, or permission of instructor
Units: 4-0-8
Lecture: TR12.30-2.30 (66-160)
______
Covers aspects of microbial genetic and genomic analyses, central dogma, horizontal gene transfer, and evolution.
A. D. Grossman, G. Fournier
Textbooks (Fall 2016)

1.871 Computational Ecology
(New)
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Lecture: MW10.30-12
______
Using high-throughput genome sequencing data, covers how to reconstruct the short-term ecological and long-term evolutionary dynamics of biological communities and populations. Emphasizes computational tools central to modern microbial ecology. Topics include computational phylogenetics, population genomics, ecological metagenomics, and ecological interactions.
O. Cordero
No required or recommended textbooks

1.88 Physical Ecology at the Microscale
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Designed for students in fluid mechanics and engineering who want to explore applications of physics and fluids to biology and ecology, and for students in the biological sciences seeking to understand the physical constraints of life at the microscale. Topics include mass exchange and flow at the scale of microbes, motility and chemotaxis, encouter rates and predation, and small-scale turbulence. Emphasizes the application of physical and fluid dynamical principles to life at the microscale, in particular (but not limited to) aquatic systems.
Staff

1.89 Environmental Microbiology
______

Graduate (Spring)
(Subject meets with1.089)
Prereq: Biology (GIR)
Units: 3-0-9
______
Provides a general introduction to the diverse roles of microorganisms in natural and artificial environments. Topics include energetics, and growth; evolution and gene flow; population and community dynamics; water and soil microbiology; biogeochemical cycling; and microorganisms in biodeterioration and bioremediation. 7.014 recommended as prerequisite; students taking graduate version complete additional assignments. Meets with 1.089A first half of term.
M. Polz, O. Cordero

1.899 Career Reengineering Program and Professional Development Workshops
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 1-0-0 [P/D/F]
______
For students in the 10-month Career Reengineering Program sponsored by the School of Engineering. Limited to CRP fellows.
Staff

Special Studies

1.95[J] Teaching College-Level Science and Engineering
______

Graduate (Fall)
(Same subject as5.95[J],7.59[J],8.395[J],18.094[J])
(Subject meets with2.978)
Prereq: None
Units: 2-0-2 [P/D/F]
Lecture: R9-11 (4-149)
______
Participatory seminar focuses on the knowledge and skills necessary for teaching science and engineering in higher education. Topics include theories of adult learning; course development; promoting active learning, problemsolving, and critical thinking in students; communicating with a diverse student body; using educational technology to further learning; lecturing; creating effective tests and assignments; and assessment and evaluation. Students research and present a relevant topic of particular interest. Appropriate for both novices and those with teaching experience.
J. Rankin
No textbook information available

1.968 Graduate Studies in Civil and Environmental Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No textbook information available

1.969 Graduate Studies in Civil and Environmental Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Individual study, research, or laboratory investigations at the graduate level under faculty supervision.
Consult Department Academic Programs Office
No textbook information available

1.982 Research in Civil and Environmental Engineering
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
For research assistants in the department, when assigned research is not used for thesis but is approved for academic credit. Credit for this subject may not be used for any degree granted by Course 1.
Consult Department Academic Programs Office
No textbook information available

1.984 Teaching Experience in Civil and Environmental Engineering
______

Graduate (Fall, Spring)
Prereq: Permission of instructor
Units: 0-2-0
URL: http://cee.mit.edu/node/20160
TBA.
______
Provides classroom teaching experience under the supervision of faculty member(s). Students prepare instructional material, deliver lectures, grade assignments, and prepare a teaching portfolio to be submitted at the end of term. Concurrent enrollment in 1.95J strongly recommended. Enrollment limited by availability of suitable teaching assignments.
Information: Academic Program Office
No textbook information available

1.999 Undergraduate Studies in Civil and Environmental Engineering
______

Undergrad (Fall, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Individual study, research, or laboratory investigations under faculty supervision.
Consult Department Academic Programs Office
No textbook information available

1.EPE UPOP Engineering Practice Experience
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.EPE,2.EPE,3.EPE,6.EPE,10.EPE,16.EPE,22.EPE)
Prereq: 2.EPW or permission of instructor
Units: 0-0-1 [P/D/F]
TBA.
______
Provides sophomores with guided practice in finding opportunities and excelling in the world of practice. Building on the skills and relationships acquired in the Engineering Practice Workshop, students receive coaching to articulate goals, invoke the UPOP network of mentors and employers, identify and pursue opportunities and negotiate terms of their summer assignment. Students complete a 10-12 week internship, which includes filing three progress reports, conducting one informational interview, and possibly hosting a site visit by MIT staff. Returning to campus as juniors, UPOP students take part in reflective exercises that aid assimilation of learning objectives and reinforce the cognitive link between all aspects of the UPOP experience and disciplinary fields of study. Sequence begins in the spring of sophomore year and ends in the fall of junior year.
Staff
No textbook information available

1.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No textbook information available

1.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of an SM, MEng, CE, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member.
Consult Department Academic Programs Office
Textbooks arranged individually

1.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of an S.B. thesis; to be arranged by the student and an appropriate MIT faculty member. Intended for seniors. Student must submit an approved thesis proposal to the Academic Programs Office by the fifth week of the first term the student is registered for thesis.
Consult Department Academic Programs Office
Textbooks arranged individually

1.UR Research in Civil and Environmental Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually

1.URG Research in Civil and Environmental Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Individual research or laboratory study under faculty supervision. Also opportunities in ongoing research program.
Consult Department Academic Programs Office
Textbooks arranged individually

1.S82 Special Problems in Environmental Microbiology and Chemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Advanced study of topics not covered in the regular subject listings, particularly seminar, laboratory, and experimental subjects offered by permanent or visiting faculty. Addresses topics in environmental microbiology, ecological genomics, microbial evolution and population genetics, oceanography, biogeochemical processes, environmental organic chemistry and aquatic chemistry.
S. W. Chisholm, M. F. Polz, E. J. Alm, P. M. Gschwend, H. F. Hemond
No required or recommended textbooks

1.S977 Special Graduate Subject in Civil and Environmental Engineering
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Graduate subjects taught experimentally; subjects offered by visiting faculty; and seminars on topics of current interest not included in the regular curriculum. 1.978 is taught P/D/F.
Consult Department Academic Programs Office
No textbook information available

1.S978 Special Graduate Subject in Civil and Environmental Engineering
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of Instructor
Units arranged [P/D/F]
TBA.
______
No textbook information available

1.S979 Special Graduate Subject in Civil and Environmental Engineering
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
URL: https://learning-modules.mit.edu/class/index.html?uuid=/course/1/sp16/1.S979
TBA.
______
Graduate subjects taught experimentally; subjects offered by visiting faculty; and seminars on topics of current interest not included in the regular curriculum. 1.978 is taught P/D/F.
Consult Department Academic Programs Office
No textbook information available

1.S980 Special Graduate Subject in Civil and Environmental Engineering
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Graduate subjects taught experimentally; subjects offered by visiting faculty; and seminars on topics of current interest not included in the the regular curriculum. 1.978 is taught P/D/F/.
Staff
No textbook information available

1.S981 Special Graduate Subject in Civil and Environmental Engineering
______

Graduate (Fall, IAP, Spring, Summer); first half of term
Prereq: Permission of Instructor
Units arranged
TBA.
______
Graduate subjects taught experimentally; subjects offered by visiting faculty; and seminars on topics of current interest not included in the the regular curriculum. 1.S978 is taught P/D/F.
Staff
No textbook information available

1.S982 Special Graduate Subject in Civil and Environmental Engineering
______

Graduate (Fall, IAP, Spring, Summer); second half of term
Prereq: Permission of Instructor
Units arranged
TBA.
______
Graduate subjects taught experimentally; subjects offered by visiting faculty; and seminars on topics of current interest not included in the the regular curriculum. 1.S978 is taught P/D/F/.
Staff
No textbook information available

1.S991 Special Undergraduate Subject in Civil and Environmental Engineering
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No textbook information available

1.S992 Special Undergraduate Subject in Civil and Environmental Engineering
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Subjects taught experimentally; subjects offered by visiting faculty; and seminars on topics of current interest not included in the regular curriculum. 1.S991 is taught P/D/F.
Consult Department Academic Programs Office
No textbook information available

1.S993 Special Undergraduate Subject in Civil and Environmental Engineering
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: TR1 (1-242) Lab: F2-4 (1-050)
______
Subjects taught experimentally; subjects offered by visiting faculty; and seminars on topics of current interest not included in the regular curriculum. 1.S991 is taught P/D/F.
Consult Department Academic Programs Office
No required or recommended textbooks


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Produced: 26-SEP-2016 05:10 PMFall 2016 Course 2: Mechanical Engineering
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Course 2: Mechanical Engineering
Fall 2016


Freshman Year Introductory Subjects

2.00A[J] Fundamentals of Engineering Design: Explore Space, Sea and Earth
______

Undergrad (Spring)
Not offered regularly; consult department
(Same subject as16.00A[J])
Prereq: Physics I (GIR), Calculus I (GIR)
Units: 3-3-3
______
Student teams formulate and complete space/earth/ocean exploration-based design projects with weekly milestones. Introduces core engineering themes, principles, and modes of thinking. Specialized learning modules enable teams to focus on the knowledge required to complete their projects, such as machine elements, electronics, design process, visualization and communication. Includes exercises in written and oral communication and team building. Examples of projects include surveying a lake for millfoil, from a remote controlled aircraft, and then sending out robotic harvesters to clear the invasive growth; and exploration to search for the evidence of life on a moon of Jupiter, with scientists participating through teleoperation and supervisory control of robots. Enrollment limited; preference to freshmen.
A. H. Techet, D. Newman

2.00B Toy Product Design
______

Undergrad (Spring)
Prereq: None
Units: 3-5-1
______
Provides students with an overview of design for entertainment and play, as well as opportunities in creative product design and community service. Students develop ideas for new toys that serve clients in the community, and work in teams with local sponsors and with experienced mentors on a themed toy design project. Students enhance creativity and experience fundamental aspects of the product development process, including determining customer needs, brainstorming, estimation, sketching, sketch modeling, concept development, design aesthetics, detailed design, and prototyping. Includes written, visual, and oral communication. Enrollment limited; preference to freshmen.
D. R. Wallace

Core Undergraduate Subjects

2.00 Introduction to Design
______

Undergrad (Fall); second half of term
Prereq: None
Units: 2-2-2
Begins Oct 24. Lecture: MW3.30-5 (3-370) Lab: R2-5 (35-307) or F9.30-12.30 (35-307) or F2-5 (35-307)
______
Project-based introduction to product development and engineering design. Emphasizes key elements of the design process, including defining design problems, generating ideas, and building solutions. Presents a range of design techniques to help students think about, evaluate, and communicate designs, from sketching to physical prototyping, as well as other types of modeling. Students work both individually and in teams. Enrollment limited; preference to Course 2-A sophomores.
M. Yang
No required or recommended textbooks

2.001 Mechanics and Materials I
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Physics I (GIR);Coreq: 18.03 or 2.087
Units: 3-2-7
Lecture: TR11-12.30 (10-250) Lab: TBA Recitation: M9.30-11 (5-134) or M11-12.30 (5-217) or M2-3.30 (5-134) or M3.30-5 (5-217) or T9.30-11 (5-234) or T1-2.30 (5-233) or T2.30-4 (5-233) or T EVE (7-8.30 PM) (5-233) +final
______
Introduction to statics and the mechanics of deformable solids. Emphasis on the three basic principles of equilibrium, geometric compatibility, and material behavior. Stress and its relation to force and moment; strain and its relation to displacement; linear elasticity with thermal expansion. Failure modes. Application to simple engineering structures such as rods, shafts, beams, and trusses. Application to biomechanics of natural materials and structures.
G. Barbastathis, A. E. Hosoi, K. Kamrin
No required or recommended textbooks

2.002 Mechanics and Materials II
______

Undergrad (Spring)
Prereq: 2.001; Chemistry (GIR)
Units: 3-3-6
______
Introduces mechanical behavior of engineering materials, and the use of materials in mechanical design. Emphasizes the fundamentals of mechanical behavior of materials, as well as design with materials. Major topics: elasticity, plasticity, limit analysis, fatigue, fracture, and creep. Materials selection. Laboratory experiments involving projects related to materials in mechanical design. Enrollment may be limited due to laboratory capacity; preference to Course 2 majors and minors.
L. Anand, K. Kamrin, P. Reis

2.003[J] Dynamics and Control I
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
(Same subject as1.053[J])
Prereq: Physics II;Coreq: 18.03 or 2.087
Units: 4-1-7
Lecture: TR9.30-11 (10-250) Recitation: R12 (5-233) or R1 (5-233) or R3 (5-233) or R4 (5-233) or F2 (1-246) or F3 (1-246) +final
______
Introduction to the dynamics and vibrations of lumped-parameter models of mechanical systems. Kinematics. Force-momentum formulation for systems of particles and rigid bodies in planar motion. Work-energy concepts. Virtual displacements and virtual work. Lagrange's equations for systems of particles and rigid bodies in planar motion. Linearization of equations of motion. Linear stability analysis of mechanical systems. Free and forced vibration of linear multi-degree of freedom models of mechanical systems; matrix eigenvalue problems.
J. K. Vandiver, N. C. Makris, N. M. Patrikalakis, T. Peacock, D. Gossard, K. Turitsyn
No required or recommended textbooks

2.004 Dynamics and Control II
______

Undergrad (Fall, Spring)
Prereq: 2.003 or 2.03; Physics II (GIR)
Units: 4-2-6
Lecture: TR9.30-11,F11 (3-270) Lab: M1-3 (3-062) or M3-5 (3-062) or T1-3 (3-062) or T3-5 (3-062) +final
______
Modeling, analysis, and control of dynamic systems. System modeling: lumped parameter models of mechanical, electrical, and electromechanical systems; interconnection laws; actuators and sensors. Linear systems theory: linear algebra; Laplace transform; transfer functions, time response and frequency response, poles and zeros; block diagrams; solutions via analytical and numerical techniques; stability. Introduction to feedback control: closed-loop response; PID compensation; steady-state characteristics, root-locus design concepts, frequency-domain design concepts. Laboratory experiments and control design projects. Enrollment may be limited due to laboratory capacity; preference to Course 2 majors and minors.
G. Barbastathis, D. Del Vecchio, D. C. Gossard, D. E. Hardt, S. Lloyd
Textbooks (Fall 2016)

2.005 Thermal-Fluids Engineering I
______

Undergrad (Fall, Spring)
Prereq: Physics II (GIR), Calculus II (GIR); 2.086, 6.0002, or 18.06; or permission of instructor
Units: 5-0-7
Lecture: MW9-11 (1-190) Recitation: F11 (1-371) or F12 (1-371) or F1 (1-371) +final
______
Integrated development of the fundamental principles of thermodynamics, fluid mechanics, and heat transfer with applications. Focuses on the development of the first and second laws of thermodynamics with special consideration of the rate processes associated with heat transfer and work transfer. Entropy generation and its influence on the performance of engineering systems. Conduction heat transfer in solids including steady-state and transient situations. Finned surfaces. Coupled and uncoupled fluid models. Hydrostatics. Inviscid flow analysis and Bernoulli equation. Internal and external laminar viscous flows. Turbulence. Boundary layers. Head loss in pipes.
J. G. Brisson, J. Buongiorno, P. F. J. Lermusiaux, K. Varanasi
Textbooks (Fall 2016)

2.006 Thermal-Fluids Engineering II
______

Undergrad (Fall, Spring)
Prereq: 2.005; or 2.051, 2.06
Units: 5-0-7
Lecture: MW9.30-11,F9 (3-370) Recitation: F11 (1-242) or F1 (1-242) or F2 (1-242) +final
______
Focuses on the application of the principles of thermodynamics, heat transfer, and fluid mechanics to the design and analysis of engineering systems. Laminar and turbulent flow. Heat transfer associated with laminar and turbulent flow of fluids in free and forced convection in channels and over surfaces. Pure substance model. Heat transfer in boiling and condensation. Thermodynamics and fluid mechanics of steady flow components of thermodynamic plants. Heat exchanger design. Power cycles and refrigeration plants. Design of thermodynamic plants. Radiation heat transfer. Multi-mode heat transfer and fluid flow in thermodynamic plants.
J. G. Brisson, A. E. Hosoi, R. Karnik, G. H. McKinley
Textbooks (Fall 2016)

2.007 Design and Manufacturing I
______

Undergrad (Spring)
Prereq: 2.001; 2.670;Coreq: 2.086
Units: 3-4-5
______
Develops students' competence and self-confidence as design engineers. Emphasis on the creative design process bolstered by application of physical laws. Instruction on how to complete projects on schedule and within budget. Robustness and manufacturability are emphasized. Subject relies on active learning via a major design-and-build project. Lecture topics include idea generation, estimation, concept selection, visual thinking, computer-aided design (CAD), mechanism design, machine elements, basic electronics, technical communication, and ethics. Lab fee. Limited enrollment. Pre-registration required for lab assignment; special sections by lottery only.
D. Frey, S. Kim, A. Winter

2.008 Design and Manufacturing II
______

Undergrad (Fall, Spring) 1/2 Institute Lab
Prereq: 2.007 orCoreq: 2.017; 2.005 or 2.051
Units: 3-3-6
Lecture: MW11-12.30 (4-270) Lab: M2-5 (35-520) or T9-12 (35-308) or T2-5 (35-308) or W2-5 (35-520) or R9-12 (35-308) or R2-5 (35-308)
______
Integration of design, engineering, and management disciplines and practices for analysis and design of manufacturing enterprises. Emphasis is on the physics and stochastic nature of manufacturing processes and systems, and their effects on quality, rate, cost, and flexibility. Topics include process physics and control, design for manufacturing, and manufacturing systems. Group project requires design and fabrication of parts using mass-production and assembly methods to produce a product in quantity. Six units may be applied to the General Institute Lab Requirement. Enrollment may be limited due to laboratory capacity; preference to Course 2 majors and minors.
J.-H. Chun, M. L. Culpepper, S. Kim, S. G. Kim, S. E. Sarma, J. Hart
Textbooks (Fall 2016)

2.009 The Product Engineering Process
______

Undergrad (Fall)
Prereq: 2.001; 2.003 or 2.03; 2.005 or 2.051; 2.670, 2.678 or 2.00B
Units: 3-3-6
URL: http://web.mit.edu/2.009/www/
Lecture: MWF1 (10-250) Lab: T2-5 (3-037A) or T2-5 (3-037B) or T EVE (7-10 PM) (3-037A) or T EVE (7-10 PM) (3-037B) or T EVE (7-10 PM) (3-037C) or T EVE (7-10 PM) (3-037D) or W2-5 (3-037A) or W2-5 (3-037B) or W2-5 (3-037C) or W2-5 (3-037D) or W EVE (7-10 PM) (3-037A) or W EVE (7-10 PM) (3-037B) or R9-12 (3-037A) or R9-12 (3-037B) or R2-5 (3-037A) or R2-5 (3-037B)
______
Students develop an understanding of product development phases and experience working in teams to design and construct high-quality product prototypes. Design process learned is placed into a broader development context. Primary goals are to improve ability to reason about design alternatives and apply modeling techniques appropriate for different development phases; understand how to gather and process customer information and transform it into engineering specifications; and use teamwork to resolve the challenges in designing and building a substantive product prototype. Instruction and practice in oral communication provided. Enrollment may be limited due to laboratory capacity; preference to Course 2 seniors.
D. R. Wallace
Textbooks (Fall 2016)

2.013 Engineering Systems Design
______

Undergrad (Fall)
Prereq: 2.001; 2.003 or 2.03; 2.005 or 2.051; 2.670, 2.678 or 2.00B
Units: 0-6-6
Lecture: TR2.30-5 (NE45-202)
______
Focuses on the design of engineering systems to satisfy stated performance, stability, and/or control requirements. Emphasizes individual initiative, application of fundamental principles, and the compromises inherent in the engineering design process. Culminates in the design of an engineering system, typically a vehicle or other complex system. Includes instruction and practice in written and oral communication through team presentations, design reviews, and written reports. Enrollment may be limited due to laboratory capacity; preference to Course 2 majors and minors.
D. Hart
No required or recommended textbooks

2.014 Engineering Systems Development
______

Undergrad (Spring) Can be repeated for credit
Prereq: 2.001 or 2.01; 2.003 or 2.03; 2.005 or 2.051; 2.670, 2.678 or 2.00B
Units: 0-6-6
______
Focuses on implementation and operation of engineering systems. Emphasizes system integration and performance verification using methods of experimental inquiry. Students refine their subsystem designs and the fabrication of working prototypes. Includes experimental analysis of subsystem performance and comparison with physical models of performance and with design goals. Component integration into the full system, with detailed analysis and operation of the complete vehicle in the laboratory and in-the-field. Includes written and oral reports. Students carry out formal reviews of the overall system design. Enrollment may be limited due to laboratory capacity; preference to Course 2 majors and minors.
D. Hart

2.016 Hydrodynamics
______

Undergrad (Fall)
Prereq: 2.001
Units: 4-2-6
Lecture: TR11-12.30 (3-442) Recitation: T3 (5-134) or W4 (5-134)
______
Principles of conservation of mass, momentum and energy in fluid mechanics. Basic geophysical fluid mechanics, including the effects of salinity, temperature, and density; heat balance in the ocean; large scale flows. Hydrostatics. Linear free surface waves, wave forces on floating and submerged structures. Added mass, lift and drag forces. Introduction to ocean acoustics; sound propagation and refraction. Sonar equation. Laboratory sessions in wave propagation, lift and drag forces on submerged bodies, and sound propagation. Meets with 2.06 first half of term.
A. H. Techet, P. D. Sclavounos
Textbooks (Fall 2016)

2.017[J] Design of Electromechanical Robotic Systems
______

Undergrad (Spring) 1/2 Institute Lab
(Same subject as1.015[J])
Prereq: 2.003 or 2.03;Coreq: 2.005, 2.05 and 2.051, or 2.016; 2.671
Units: 3-3-6
______
Design, construction, and testing of field robotic systems, through team projects with each student responsible for a specific subsystem. Projects focus on electronics, instrumentation, and machine elements. Design for operation in uncertain conditions is a focus point, with ocean waves and marine structures as a central theme. Basic statistics, linear systems, Fourier transforms, random processes, spectra and extreme events with applications in design. Lectures on ethics in engineering practice included. Enrollment may be limited due to laboratory capacity.
F. S. Hover, J. J. Leonard

2.019 Design of Ocean Systems
______

Undergrad (Spring)
Prereq: 2.001; 2.003; 2.005 or 2.016
Units: 3-3-6
______
Complete cycle of designing an ocean system using computational design tools for the conceptual and preliminary design stages. Team projects assigned, with each student responsible for a specific subsystem. Lectures cover hydrodynamics; structures; power and thermal aspects of ocean vehicles, environment, materials, and construction for ocean use; generation and evaluation of design alternatives. Focus on innovative design concepts chosen from high-speed ships, submersibles, autonomous vehicles, and floating and submerged deep-water offshore platforms. Lectures on ethics in engineering practice included. Instruction and practice in oral and written communication provided. Enrollment may be limited due to laboratory capacity; preference to Course 2 seniors.
C. Chryssostomidis, M. S. Triantafyllou

2.02A Engineering Materials: Properties and Applications
______

Undergrad (Fall); first half of term
Prereq: 2.001
Units: 2-0-4
Ends Oct 21. Lecture: TR11-12.30 (3-333) Recitation: W2-3.30 (5-234)
______
Introduction to the physical mechanisms that give rise to mechanical properties of engineering materials: stiffness, creep, stress-relaxation, strength, fracture-toughness, and fatigue. Also covers materials selection for mechanical design. Includes case studies on materials-limited problems in engineering design.
A. Kolpak
Textbooks (Fall 2016)

2.03 Dynamics I
______

Undergrad (Fall, Spring); first half of term
Prereq: Physics II;Coreq: 18.03 or 2.087
Units: 2-0-4
Ends Oct 21. Lecture: TR9.30-11 (10-250) Recitation: R12 (5-233) or R1 (5-233) or R3 (5-233) or R4 (5-233) or F2 (1-246) or F3 (1-246)
______
Introduction to the dynamics of one and two degree-of-freedom mechanical systems. Kinematics. Force-momentum formulation for particles and rigid bodies. Work-energy concepts. Rotation of rigid bodies, angular momentum, torques and moments of inertia. Newton, Euler equations (direct method in dynamics). Conservation laws in dynamics. Basics of equilibrium, linearization and stability analysis. Includes MATLAB modeling of dynamical systems with applications. Meets with 2.003 first half of term.
D. Gossard, K. Turitsyn, T. Peacock
No required or recommended textbooks

2.031 Dynamics II
______

Undergrad (Fall, Spring); second half of term
Prereq: 2.03
Units: 2-0-4
Begins Oct 24. Lecture: TR9.30-11 (10-250) Recitation: R12 (5-233) or R1 (5-233) or R3 (5-233) or R4 (5-233) or F2 (1-246) or F3 (1-246) +final
______
Continuation of topics introduced in 2.03, including work-energy concepts, Lagrange's equations for systems of particles and rigid bodies in planar motion, and matrix eigenvalue problems. Meets with 2.003 second half of term.
D. Gossard, K. Turitsyn, T. Peacock
No required or recommended textbooks

2.04A Systems and Controls
______

Undergrad (Spring); second half of term
Prereq: None.Coreq: 2.03
Units: 2-1-3
______
Introduction to linear systems, transfer functions, and Laplace transforms. Covers stability and feedback, and provides basic design tools for specifications of transient response. Briefly covers frequency-domain techniques. Enrollment may be limited due to laboratory capacity.
G. Barbastathis

2.04B Introduction to Mechanical Vibration
______

Not offered academic year 2016-2017Undergrad (Fall); second half of term
Prereq: 2.03, 2.086
Units: 2-1-3
______
Analyzes the time domain response of single- and multiple-degree-of-freedom (DOF) systems to initial conditions and force inputs. Uses matrix formulation of multiple-DOF problems, including finding natural frequencies and mode shapes. Provides an introduction to the method of normal mode superposition. Includes transfer function analysis of the response of linear systems to steady state harmonic inputs, with application to vibration isolation and dynamic absorbers. Also includes application to the analysis of machines with rotating imbalances. Enrollment may be limited due to lab capacity; preference to Course 2 majors and minors.
J. K. Vandiver

2.05 Thermodynamics
______

Undergrad (Fall); first half of term
Prereq: 2.001
Units: 3-0-3
Ends Oct 21. Lecture: MW9.30-11 (3-270) Recitation: W1 (3-442) or W2 (3-442) or W3 (3-442) or W4 (3-442)
______
Provides an introduction to thermodynamics, including first law (coupled and uncoupled systems, incompressible liquid, ideal gas) and second law (equilibrium, reversibility and irreversibility). Explores systems in communication with heat reservoirs; quasi-static processes; and heat engines and refrigeration. Properties of open systems, including mass, energy and entropy transfer.
C. Buie
Textbooks (Fall 2016)

2.051 Introduction to Heat Transfer
______

Undergrad (Fall); second half of term
Prereq: 2.05
Units: 2-0-4
Begins Oct 24. Lecture: MW9.30-11 (3-270) +final
______
Introduces fundamental processes of heat transfer. Fourier's law. Heat conduction processes including thermal resistance, lumped capacitance, fins, and the heat equation. Elementary convection, including laminar and turbulent boundary layers, internal flow, and natural convection. Thermal radiation, including Stefan-Boltzmann law, small object in large enclosure, and parallel plates. Basic concepts of heat exchangers.
J. H. Lienhard, E. N. Wang, A. Hosoi
No required or recommended textbooks

2.06 Fluid Dynamics
______

Undergrad (Fall, Spring); first half of term
Prereq: 2.001
Units: 2-0-4
Ends Oct 21. Lecture: TR11-12.30 (3-442) Recitation: T3 (5-134) or W4 (5-134)
______
Introduction to principal concepts and methods of fluid mechanics. Pressure, hydrostatics, and buoyancy. Control volume analysis. Mass conservation and momentum conservation for moving fluids. Viscous fluid flows, flow through pipes. Dimensional analysis. Boundary layers, and lift and drag on objects. Meets with 2.016 first half of fall term. Also offered second half of spring term.
G. H. McKinley, K. Varanasi, A. Techet
Textbooks (Fall 2016)

2.086 Numerical Computation for Mechanical Engineers
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Physics I (GIR), Calculus II (GIR);Coreq: 18.03 or 2.087
Units: 1-3-8
1st mtg Sep 7. Room TBA. Lecture: M1 (26-100) Lab: M9-12 (W31-301) or M2-5 (1-115) or T2-5 (W31-301) or W2-5 (1-115) or F9-12 (W31-301) or F2-5 (1-115) +final
______
Covers elementary programming concepts, including variable types, data structures, and flow control. Provides an introduction to linear algebra and probability. Numerical methods relevant to MechE, including approximation (interpolation, least squares, and statistical regression), integration, solution of linear and nonlinear equations, and ordinary differential equations. Presents deterministic and probabilistic approaches. Uses examples from MechE, particularly from robotics, dynamics, and structural analysis. Assignments require MATLAB programming. Enrollment may be limited due to laboratory capacity; preference to Course 2 majors and minors.
N. Hadjiconstantinou, A. Patera, D. Frey, A. Hosoi
No textbook information available

2.087 Engineering Mathematics: Linear Algebra and ODEs
______

Undergrad (Fall, Spring); first half of term
Prereq: Calculus II (GIR), Physics I (GIR)
Units: 2-0-4
Ends Oct 21. Lecture: MW9.30-11 (3-333) Recitation: M2-3.30 (1-242)
______
Introduction to linear algebra and ordinary differential equations (ODEs), including general numerical approaches to solving systems of equations. Linear systems of equations, existence and uniqueness of solutions, Gaussian elimination. Initial value problems, 1st and 2nd order systems, forward and backward Euler, RK4. Eigenproblems, eigenvalues and eigenvectors, including complex numbers, functions, vectors and matrices.
A. Hosoi, T. Peacock
Textbooks (Fall 2016)

Dynamics and Acoustics

2.032 Dynamics
______

Graduate (Fall)
Prereq: 2.003
Units: 4-0-8
URL: http://web.mit.edu/2.032/www/
Lecture: MW1-2.30 (3-370) Recitation: T4 (1-371)
______
Review of momentum principles. Hamilton's principle and Lagrange's equations. Three-dimensional kinematics and dynamics of rigid bodies. Study of steady motions and small deviations therefrom, gyroscopic effects, causes of instability. Free and forced vibrations of lumped-parameter and continuous systems. Nonlinear oscillations and the phase plane. Nonholonomic systems. Introduction to wave propagation in continuous systems.
T. R. Akylas, T. Peacock, N. Hadjiconstantinou
No required or recommended textbooks

2.034[J] Nonlinear Dynamics and Waves
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as1.685[J],18.377[J])
Prereq: Permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/2.034/www/
______
A unified treatment of nonlinear oscillations and wave phenomena with applications to mechanical, optical, geophysical, fluid, electrical and flow-structure interaction problems. Nonlinear free and forced vibrations; nonlinear resonances; self-excited oscillations; lock-in phenomena. Nonlinear dispersive and nondispersive waves; resonant wave interactions; propagation of wave pulses and nonlinear Schrodinger equation. Nonlinear long waves and breaking; theory of characteristics; the Korteweg-de Vries equation; solitons and solitary wave interactions. Stability of shear flows. Some topics and applications may vary from year to year.
T. R. Akylas, R. R. Rosales

2.036[J] Nonlinear Dynamics and Chaos
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as18.385[J])
Prereq: 18.03 or 18.034
Units: 3-0-9
URL: http://math.mit.edu/classes/18.385
Lecture: TR11-12.30 (2-136)
______
Introduction to the theory of nonlinear dynamical systems with applications from science and engineering. Local and global existence of solutions, dependence on initial data and parameters. Elementary bifurcations, normal forms. Phase plane, limit cycles, relaxation oscillations, Poincare-Bendixson theory. Floquet theory. Poincare maps. Averaging. Near-equilibrium dynamics. Synchronization. Introduction to chaos. Universality. Strange attractors. Lorenz and Rossler systems. Hamiltonian dynamics and KAM theory. Uses MATLAB computing environment.
R. R. Rosales
Textbooks (Fall 2016)

2.050[J] Nonlinear Dynamics: Chaos
______

Undergrad (Fall)
(Same subject as12.006[J],18.353[J])
Prereq: 18.03 or 18.034; Physics II (GIR)
Units: 3-0-9
Lecture: TR1-2.30 (2-105)
______
Introduction to nonlinear dynamics and chaos in dissipative systems. Forced and parametric oscillators. Phase space. Periodic, quasiperiodic, and aperiodic flows. Sensitivity to initial conditions and strange attractors. Lorenz attractor. Period doubling, intermittency, and quasiperiodicity. Scaling and universality. Analysis of experimental data: Fourier transforms, Poincare sections, fractal dimension, and Lyapunov exponents. Applications to mechanical systems, fluid dynamics, physics, geophysics, and chemistry. See 12.207J/18.354J for Nonlinear Dynamics: Continuum Systems.
P-T. Brun
Textbooks (Fall 2016)

2.060[J] Structural Dynamics and Vibrations
______

Graduate (Fall)
(Same subject as1.581[J],16.221[J])
(Subject meets with1.058)
Prereq: Permission of instructor
Units: 3-1-8
Lecture: MWF10 (1-390) Recitation: W4 (1-246)
______
Single- and multiple-degree-of-freedom vibration problems, using matrix formulation and normal mode superposition methods. Time and frequency domain solution techniques including convolution and Fourier transforms. Applications to vibration isolation, damping treatment, and dynamic absorbers. Analysis of continuous systems by exact and approximate methods. Applications to buildings, ships, aircraft and offshore structures. Vibration measurement and analysis techniques. Students should possess basic knowledge in structural mechanics and in linear algebra. Students taking graduate version complete additional assignments.
E. Kausel, J. K. Vandiver
No textbook information available

2.062[J] Wave Propagation
______

Graduate (Spring)
(Same subject as1.138[J],18.376[J])
Prereq: 2.003, 18.075
Units: 3-0-9
URL: http://math.mit.edu/classes/18.376/
______
Theoretical concepts and analysis of wave problems in science and engineering with examples chosen from elasticity, acoustics, geophysics, hydrodynamics, blood flow, nondestructive evaluation, and other applications. Progressive waves, group velocity and dispersion, energy density and transport. Reflection, refraction and transmission of plane waves by an interface. Mode conversion in elastic waves. Rayleigh waves. Waves due to a moving load. Scattering by a two-dimensional obstacle. Reciprocity theorems. Parabolic approximation. Waves on the sea surface. Capillary-gravity waves. Wave resistance. Radiation of surface waves. Internal waves in stratified fluids. Waves in rotating media. Waves in random media.
T. R. Akylas, R. R. Rosales

2.065 Acoustics and Sensing
______

Undergrad (Spring)
(Subject meets with2.066)
Prereq: 2.003, 2.04B, 6.003, 8.03, or 16.003
Units: 3-0-9
______

2.066 Acoustics and Sensing
______

Graduate (Spring)
(Subject meets with2.065)
Prereq: 2.003, 2.04B, 6.003, 8.03, 16.003, or permission of instructor
Units: 3-0-9
______
Introduces the fundamental concepts of acoustics and sensing with waves. Provides a unified theoretical approach to the physics of image formation through scattering and wave propagation in sensing. The linear and nonlinear acoustic wave equation, sources of sound, including musical instruments. Reflection, refraction, transmission and absorption. Bearing and range estimation by sensor array processing, beamforming, matched filtering, and focusing. Diffraction, bandwidth, ambient noise and reverberation limitations. Scattering from objects, surfaces and volumes by Green's Theorem. Forward scatter, shadows, Babinet's principle, extinction and attenuation. Ray tracing and waveguides in remote sensing. Applications to acoustic, radar, seismic, thermal and optical sensing and exploration. Students taking the graduate version of the subject complete additional assignments.
N. C. Makris

Solid Mechanics and Materials

2.071 Mechanics of Solid Materials
______

Graduate (Spring)
Prereq: 2.002 or 2.02A
Units: 4-0-8
______
Fundamentals of solid mechanics applied to the mechanical behavior of engineering materials. Kinematics of deformation, stress, and balance principles. Isotropic linear elasticity and isotropic linear thermal elasticity. Variational and energy methods. Linear viscoelasticity. Small-strain elastic-plastic deformation. Mechanics of large deformation; nonlinear hyperelastic material behavior. Foundations and methods of deformable-solid mechanics, including relevant applications. Provides base for further study and specialization within solid mechanics, including continuum mechanics, computational mechanics (e.g., finite-element methods), plasticity, fracture mechanics, structural mechanics, and nonlinear behavior of materials.
L. Anand, D. M. Parks

2.072 Mechanics of Continuous Media
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 2.071
Units: 3-0-9
______
Principles and applications of continuum mechanics. Kinematics of deformation. Thermomechanical conservation laws. Stress and strain measures. Constitutive equations including some examples of their microscopic basis. Solution of some basic problems for various materials as relevant in materials science, fluid dynamics, and structural analysis. Inherently nonlinear phenomena in continuum mechanics. Variational principles.
L. Anand

2.073 Solid Mechanics: Plasticity and Inelastic Deformation
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 2.071
Units: 3-0-9
Lecture: MW2.30-4 (1-150)
______
Physical basis of plastic/inelastic deformation of solids; metals, polymers, granular/rock-like materials. Continuum constitutive models for small and large deformation of elastic-(visco)plastic solids. Analytical and numerical solution of selected boundary value problems. Applications to deformation processing of metals.
L. Anand, D. M. Parks
No textbook information available

2.074 Solid Mechanics: Elasticity
______

Graduate (Fall)
Prereq: 2.002,Coreq: 18.03
Units: 3-0-9
Lecture: MW11-12.30 (1-150) +final
______
Introduction to the theory and applications of elastic solids. Review strain, stress, and stress-strain law. Several of the following topics: Anisotropic material behavior. Piezoelectric materials. Effective properties of composites. Structural mechanics of beams and plates. Energy methods for structures. Two-dimensional problems. Stress concentration at cavities, concentrated loads, cracks, and dislocations. Variational methods and their applications; introduction to the finite element method. Introduction to wave propagation.
R. Abeyaratne
No required or recommended textbooks

2.076[J] Mechanics of Heterogeneous Materials
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as16.223[J])
Prereq: 2.002, 3.032, 16.20, or permission of instructor
Units: 3-0-9
______
Mechanical behavior of heterogeneous materials such as thin-film microelectro- mechanical systems (MEMS) materials and advanced filamentary composites, with particular emphasis on laminated structural configurations. Anisotropic and crystallographic elasticity formulations. Structure, properties and mechanics of constituents such as films, substrates, active materials, fibers, and matrices including nano- and micro-scale constituents. Effective properties from constituent properties. Classical laminated plate theory for modeling structural behavior including extrinsic and intrinsic strains and stresses such as environmental effects. Introduction to buckling of plates and nonlinear (deformations) plate theory. Other issues in modeling heterogeneous materials such as fracture/failure of laminated structures.
B. L. Wardle, S-G. Kim

2.080[J] Structural Mechanics
______

Graduate (Fall)
(Same subject as1.573[J])
Prereq: 2.002
Units: 4-0-8
Lecture: MW2.30-4 (2-105) Recitation: F9 (3-442)
______
Presents fundamental concepts of structural mechanics with applications to marine, civil, and mechanical structures. Covers residual stresses; thermal effects; analysis of beams, columns, tensioned beams, trusses, frames, arches, cables, and shafts of general shape and material, including composites; elastic buckling of columns; exact and approximate methods, energy methods, principle of virtual work, and introduction to computational structural mechanics.
T. Wierzbicki, H. Schmidt
Textbooks (Fall 2016)

2.081[J] Plates and Shells: Static and Dynamic Analysis
______

Graduate (Spring)
(Same subject as16.230[J])
Prereq: 2.071, 2.080, or permission of instructor
Units: 3-1-8
______
Stress-strain relations for plate and shell elements. Differential equations of equilibrium. Energy methods and approximate solutions. Bending and buckling of rectangular plates. Post-buckling and ultimate strength of cold formed sections and typical stiffened panels used in aerospace, civil, and mechanical engineering; offshore technology; and ship building. Geometry of curved surfaces. General theory of elastic, axisymmetric shells and their equilibrium equations. Buckling, crushing and bending strength of cylindrical shells with applications. Propagation of 1-D elastic waves in rods, geometrical and material dispersion. Plane, Rayleigh surface, and 3-D waves. 1-D plastic waves. Response of plates and shells to high-intensity loads. Dynamic plasticity and fracture. Application to crashworthiness and impact loading of structures.
T. Sapsis

2.082 Ship Structural Analysis and Design
______

Graduate (Spring); second half of term
Prereq: 2.081, 2.701
Units: 3-0-3
______
Design application of analysis developed in 2.081J. Ship longitudinal strength and hull primary stresses. Ship structural design concepts. Design limit states including plate bending, column and panel buckling, panel ultimate strength, and plastic analysis. Matrix stiffness, and introduction to finite element analysis. Computer projects on the structural design of a midship module.
R. S. McCord, T. Wierzbicki

2.084[J] Structural Mechanics in Nuclear Power Technology
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as1.56[J],22.314[J])
Prereq: 2.001 or permission of instructor
Units: 3-0-9
______
Structural components in nuclear power plant systems, their functional purposes, operating conditions, and mechanical/structural design requirements. Combines mechanics techniques with models of material behavior to determine adequacy of component design. Considerations include mechanical loading, brittle fracture, inelastic behavior, elevated temperatures, neutron irradiation, vibrations and seismic effects.
Staff

Computational Engineering

2.089[J] Computational Geometry
______

Graduate (Spring)
Not offered regularly; consult department
(Same subject as1.128[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Topics in surface modeling: b-splines, non-uniform rational b-splines, physically based deformable surfaces, sweeps and generalized cylinders, offsets, blending and filleting surfaces. Non-linear solvers and intersection problems. Solid modeling: constructive solid geometry, boundary representation, non-manifold and mixed-dimension boundary representation models, octrees. Robustness of geometric computations. Interval methods. Finite and boundary element discretization methods for continuum mechanics problems. Scientific visualization. Variational geometry. Tolerances. Inspection methods. Feature representation and recognition. Shape interrogation for design, analysis, and manufacturing. Involves analytical and programming assignments.
N. M. Patrikalakis, D. C. Gossard

2.091[J] Software and Computation for Simulation
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as1.124[J])
Prereq: 1.00 or permission of instructor
Units: 3-0-9
______
Modern software development techniques and algorithms for engineering computation. Hands-on investigation of computational and software techniques for simulating engineering systems, such as sensor networks, traffic networks, and discrete simulation of materials using atomistic and particle methods. Covers data structures and algorithms for modeling, analysis, and visualization in the setting of multi-core and distributed computing. Treatment of basic topics, such as queuing, sorting and search algorithms, and more advanced numerical techniques based on state machines and distributed agents. Foundation for in-depth exploration of image processing, optimization, finite element and particle methods, computational materials, discrete element methods, and network methods. Knowledge of an object-oriented language required.
J. R. Williams

2.092 Finite Element Analysis of Solids and Fluids I
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with2.093)
Prereq: 2.001; 2.003 or 2.03
Units: 3-0-9
URL: http://ocw.mit.edu/courses/mechanical-engineering/2-092-finite-element-analysis-of-solids-and-fluids-i-fall-2009/index.htm
______

2.093 Finite Element Analysis of Solids and Fluids I
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with2.092)
Prereq: 2.001; 2.003 or 2.03
Units: 3-0-9
URL: http://ocw.mit.edu/courses/mechanical-engineering/2-092-finite-element-analysis-of-solids-and-fluids-i-fall-2009/index.htm
______
Finite element methods for analysis of steady-state and transient problems in solid, structural, fluid mechanics, and heat transfer. Presents finite element methods and solution procedures for linear and nonlinear analyses using largely physical arguments. Demonstrates finite element analyses. Homework involves use of an existing general purpose finite element analysis program. Includes modeling of problems and interpretation of numerical results. Students taking graduate version complete additional assignments.
K. J. Bathe

2.094 Finite Element Analysis of Solids and Fluids II
______

Graduate (Spring)
Prereq: 2.001
Units: 3-0-9
______
Presents finite element theory and methods for general linear and nonlinear analyses. Reliable and effective finite element methods and their applications to solution of general problems in solid, structural and fluid mechanics, heat and mass transfer, and multiphysics problems including fluid-structure interactions. Formulation of governing continuum mechanics equations, conservation laws, virtual work, and variational principles for finite element solutions. Discretization of governing equations using finite element methods; stability, accuracy and convergence of methods. Solution of central problems and a term project using an existing general purpose finite element analysis program.
K. J. Bathe

2.096[J] Introduction to Numerical Simulation
______

Graduate (Fall)
(Same subject as6.336[J],16.910[J])
Prereq: 18.03 or 18.06
Units: 3-3-6
Lecture: MW1-2.30 (32-141)
______
Introduction to computational techniques for the simulation of a large variety of engineering and physical systems. Applications are drawn from aerospace, mechanical, electrical, chemical engineering, biology, and materials science. Topics include mathematical formulations (techniques for automatic assembly of mathematical problems from physics' principles); sparse, direct and iterative solution techniques for linear systems; Newton and Homotopy methods for nonlinear problems; discretization methods for ordinary, time-periodic and partial differential equations; accelerated methods for integral equations; techniques for automatic generation of compact dynamical system models and model order reduction.
L. Daniel, J. K. White
No required or recommended textbooks

2.097[J] Numerical Methods for Partial Differential Equations
______

Graduate (Fall)
(Same subject as6.339[J],16.920[J])
Prereq: 18.03 or 18.06
Units: 3-0-9
Lecture: MW9.30-11 (4-163)
______
Covers the fundamentals of modern numerical techniques for a wide range of linear and nonlinear elliptic, parabolic, and hyperbolic partial differential and integral equations. Topics include mathematical formulations; finite difference, finite volume, finite element, and boundary element discretization methods; and direct and iterative solution techniques. The methodologies described form the foundation for computational approaches to engineering systems involving heat transfer, solid mechanics, fluid dynamics, and electromagnetics. Computer assignments requiring programming.
Q. Wang, J. K. White
No textbook information available

2.099[J] Computational Mechanics of Materials
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as16.225[J])
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Formulation of numerical (finite element) methods for the analysis of the nonlinear continuum response of materials. The range of material behavior considered includes finite deformation elasticity and inelasticity. Numerical formulation and algorithms include variational formulation and variational constitutive updates; finite element discretization; constrained problems; time discretization and convergence analysis. Strong emphasis on the (parallel) computer implementation of algorithms in programming assignments. The application to real engineering applications and problems in engineering science are stressed throughout. Experience in either C++, C, or Fortran required.
R. Radovitzky

System Dynamics and Control

2.110[J] Information, Entropy, and Computation
______

Undergrad (Spring)
(Same subject as6.050[J])
Prereq: Physics I (GIR)
Units: 3-0-6
______
Explores the ultimate limits to communication and computation, with an emphasis on the physical nature of information and information processing. Topics include information and computation, digital signals, codes, and compression. Biological representations of information. Logic circuits, computer architectures, and algorithmic information. Noise, probability, and error correction. The concept of entropy applied to channel capacity and to the second law of thermodynamics. Reversible and irreversible operations and the physics of computation. Quantum computation.
P. Penfield, Jr., S. Lloyd

2.111[J] Quantum Computation
______

Graduate (Fall)
(Same subject as8.370[J],18.435[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (4-370) +final
______
Provides an introduction to the theory and practice of quantum computation. Topics covered: physics of information processing; quantum algorithms including the factoring algorithm and Grover's search algorithm; quantum error correction; quantum communication and cryptography. Knowledge of quantum mechanics helpful but not required.
I. Chuang, E. Farhi, S. Lloyd, P. Shor
Textbooks (Fall 2016)

2.12 Introduction to Robotics
______

Undergrad (Fall)
(Subject meets with2.120)
Prereq: 2.004, or 2.031 and 2.04A
Units: 3-2-7
Lecture: MW2.30-4 (3-270) Lab: R11-1 (5-007) or R1-3 (5-007) or R3-5 (5-007) or F9-11 (5-007) or F11-1 (5-007) or F2-4 (5-007)
______
No required or recommended textbooks

2.120 Introduction to Robotics
______

Graduate (Fall)
(Subject meets with2.12)
Prereq: 2.004, or 2.031 and 2.04A, or permission of instructor
Units: 3-2-7
Lecture: MW2.30-4 (3-270) Lab: R11-1 (5-007) or R1-3 (5-007) or R3-5 (5-007) or F9-11 (5-007) or F11-1 (5-007) or F2-4 (5-007)
______
Presents the fundamentals of robot mechanisms, dynamics, and controls. Planar and spatial kinematics, differential motion, energy method for robot mechanics; mechanism design for manipulation and locomotion; multi-rigid-body dynamics; force and compliance control, balancing control, visual feedback, human-machine interface; actuators, sensors, wireless networking, and embedded software. Weekly laboratories include real-time control, vehicle navigation, arm and end-effector design, and balancing robot control. Group term project requires design and fabrication of robotic systems. Students taking graduate version complete additional assignments. Enrollment may be limited due to laboratory capacity.
H. Asada, J. J. Leonard
No required or recommended textbooks

2.131 Advanced Instrumentation and Measurement
______

Graduate (Spring)
Prereq: Permission of Instructor
Units: 3-6-3
______
Provides training in advanced instrumentation and measurement techniques. Topics include system level design, fabrication and evaluation with emphasis on systems involving concepts and technology from mechanics, optics, electronics, chemistry and biology. Simulation, modeling and design software. Use of a wide range of instruments/techniques (e.g., scanning electron microscope, dynamic signal/system analyzer, impedance analyzer, laser interferometer) and fabrication/machining methods (e.g., laser micro-machining, stereo lithography, computer controlled turning and machining centers). Theory and practice of both linear and nonlinear system identification techniques. No final exam.
I. W. Hunter

2.14 Analysis and Design of Feedback Control Systems
______

Undergrad (Spring)
(Subject meets with2.140)
Prereq: 2.004, 2.04A, or 2.04B
Units: 3-3-6
URL: http://me.mit.edu/2.14/
______

2.140 Analysis and Design of Feedback Control Systems
______

Graduate (Spring)
(Subject meets with2.14)
Prereq: 2.004, 2.04A, 2.04B, or permission of instructor
Units: 3-3-6
______
Develops the fundamentals of feedback control using linear transfer function system models. Analysis in time and frequency domains. Design in the s-plane (root locus) and in the frequency domain (loop shaping). Describing functions for stability of certain non-linear systems. Extension to state variable systems and multivariable control with observers. Discrete and digital hybrid systems and use of z-plane design. Extended design case studies and capstone group projects. Student taking graduate version complete additional assignments. Enrollment may be limited due to laboratory capacity.
D. Rowell, D. L. Trumper, K. Youcef-Toumi

2.141 Modeling and Simulation of Dynamic Systems
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 2.151
Units: 3-0-9
______
Modeling multidomain engineering systems at a level of detail suitable for design and control system implementation. Network representation, state-space models; multiport energy storage and dissipation, Legendre transforms; nonlinear mechanics, transformation theory, Lagrangian and Hamiltonian forms; Control-relevant properties. Application examples may include electro-mechanical transducers, mechanisms, electronics, fluid and thermal systems, compressible flow, chemical processes, diffusion, and wave transmission.
N. Hogan

2.151 Advanced System Dynamics and Control
______

Graduate (Fall)
Prereq: 2.004, 18.06; or 2.087, 2.04A
Units: 4-0-8
Lecture: TR1-2.30 (3-370) Recitation: W4 (37-212)
______
Analytical descriptions of state-determined dynamic physical systems; time and frequency domain representations; system characteristics - controllability, observability, stability; linear and nonlinear system responses. Modification of system characteristics using feedback. State observers, Kalman filters. Modeling/performance trade-offs in control system design. Basic optimization tools. Positive systems. Emphasizes applications to physical systems.
J.-J. E. Slotine, K. Youcef-Toumi, N. Hogan
Textbooks (Fall 2016)

2.152[J] Nonlinear Control
______

Graduate (Spring)
(Same subject as9.110[J])
Prereq: 2.151, 6.241, 16.31, or permission of instructor
Units: 3-0-9
______
Introduction to nonlinear control and estimation in physical and biological systems. Nonlinear stability theory, Lyapunov analysis, Barbalat's lemma. Feedback linearization, differential flatness, internal dynamics. Sliding surfaces. Adaptive nonlinear control and estimation. Multiresolution bases, nonlinear system identification. Contraction analysis, differential stability theory. Nonlinear observers. Asynchronous distributed computation and learning. Concurrent synchronization, polyrhythms. Monotone nonlinear systems. Emphasizws application to physical systems (robots, aircraft, spacecraft, underwater vehicles, reaction-diffusion processes, machine vision, oscillators, internet), machine learning, computational neuroscience, and systems biology. Includes term projects.
J.-J. E. Slotine

2.153 Adaptive Control
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 2.151
Units: 3-0-9
______
Introduces the foundation of adaptive control in continuous-time and discrete-time systems. Adaptive control is the ability to self-correct a controller in the presence of parametric uncertainties using online information is its main and most compelling feature. Examples drawn from aerospace, propulsion, automotive, and energy systems will be used to elucidate the underlying concepts.
A. Annaswamy

2.154 Maneuvering and Control of Surface and Underwater Vehicles
______

Graduate (Fall)
Prereq: 2.22
Units: 3-0-9
Lecture: TR9.30-11 (1-132)
______
Maneuvering motions of surface and underwater vehicles. Derivation of equations of motion, hydrodynamic coefficients. Memory effects. Linear and nonlinear forms of the equations of motion. Control surfaces modeling and design. Engine, propulsor, and transmission systems modeling and simulation during maneuvering. Stability of motion. Principles of multivariable automatic control. Optimal control, Kalman filtering, loop transfer recovery. Term project: applications chosen from autopilots for surface vehicles; towing in open seas; remotely operated vehicles.
M. S. Triantafyllou
No required or recommended textbooks

2.160 Identification, Estimation, and Learning
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 2.151
Units: 3-0-9
______
Provides a broad theoretical basis for system identification, estimation, and learning. Least squares estimation and its convergence properties, Kalman filter and extended Kalman filter, noise dynamics and system representation, function approximation theory, neural nets, radial basis functions, wavelets, Volterra expansions, informative data sets, persistent excitation, asymptotic variance, central limit theorems, model structure selection, system order estimate, maximum likelihood, unbiased estimates, Cramer-Rao lower bound, Kullback-Leibler information distance, Akaike's information criterion, experiment design, and model validation.
H. Asada, J.-J. E. Slotine

2.165[J] Robotics
______

Graduate (Spring)
(Same subject as9.175[J])
Prereq: 2.151 or permission of instructor
Units: 3-0-9
______
Dynamic analysis, design, and control of robots. Forward and inverse kinematics and dynamics of multi-input, multi-output rigid body systems. Computed torque control. Adaptive control. System identification. Force feedback, adaptive visual servoing. Task planning, teleoperation. Elements of biological planning and control. Motor primitives, entrainment, locomotion, active sensing, binding models. Term projects.
J.-J. E. Slotine, H. Asada

2.166 Autonomous Vehicles
______

Graduate (Spring)
Prereq: 6.041B or permission of instructor
Units: 3-1-8
______
Theory and application of probabilistic techniques for autonomous mobile robotics. Topics include probabilistic state estimation and decision making for mobile robots; stochastic representations of the environment; dynamic models and sensor models for mobile robots; algorithms for mapping and localization; planning and control in the presence of uncertainty; cooperative operation of multiple mobile robots; mobile sensor networks; application to autonomous marine (underwater and floating), ground, and air vehicles.
J. J. Leonard

2.167 Hands-On Marine Robotics
______

Not offered academic year 2016-2017Undergrad (Fall) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
______
Direct experience in developing marine robotic systems, from conceptualization and design through manufacture and testing. The class consists of a weekly seminar with readings and discussions, and significant outside work on student projects, culminating in a written report each term. Seminar topics include tools for unmanned marine work and their history, analysis of mission requirements, conceptual design and modeling of systems, experiments and proofs of concept, and project pacing and time management. A total of up to 12 hours credit may be taken over one or two terms; seminar topics repeat yearly.
F. S. Hover

2.171 Analysis and Design of Digital Control Systems
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 2.14, 2.151, or permission of instructor
Units: 3-3-6
URL: http://web.mit.edu/2.171/www/
Subject Cancelled Subject Cancelled
______
A comprehensive introduction to digital control system design, reinforced with hands-on laboratory experiences. Major topics include discrete-time system theory and analytical tools; design of digital control systems via approximation from continuous time; direct discrete-time design; loop-shaping design for performance and robustness; state-space design; observers and state-feedback; quantization and other nonlinear effects; implementation issues. Laboratory experiences and design projects connect theory with practice.
D. L. Trumper

2.18[J] Biomolecular Feedback Systems
______

Graduate (Spring)
(Same subject as6.557[J])
(Subject meets with2.180[J],6.027[J])
Prereq: 18.03, Biology (GIR), or permission of instructor
Units: 3-0-9
______

2.180[J] Biomolecular Feedback Systems
______

Undergrad (Spring)
(Same subject as6.027[J])
(Subject meets with2.18[J],6.557[J])
Prereq: 18.03, Biology (GIR), or permission of instructor
Units: 3-0-9
______
Comprehensive introduction to dynamics and control of biomolecular systems with emphasis on design/analysis techniques from control theory. Provides a review of biology concepts, regulation mechanisms, and models. Covers basic enabling technologies, engineering principles for designing biological functions, modular design techniques, and design limitations. Students taking graduate version complete additional assignments.
D. Del Vecchio

2.183[J] Biomechanics and Neural Control of Movement
______

Graduate (Spring)
(Same subject as9.34[J])
(Subject meets with2.184)
Prereq: 2.004, 2.04A, or permission of instructor
Units: 3-0-9
______

2.184 Biomechanics and Neural Control of Movement
______

Undergrad (Spring)
(Subject meets with2.183[J],9.34[J])
Prereq: 2.004, 2.04A, or permission of instructor
Units: 3-0-9
______
Quantitative knowledge of human movement behavior is important in a growing number of engineering applications (medical and rehabilitation technology, athletic and military equipment, human-computer interaction, vehicle performance, etc.). Presents a quantitative, model-based description of how biomechanical and neural factors interact in human sensory-motor behavior, focusing mainly on the upper limbs. Students survey recent literature on how motor behavior is controlled, comparing biological and robotic approaches to similar tasks. Topics may include a review of relevant neural, muscular and skeletal physiology, neural feedback and "equilibrium-point" theories, co-contraction strategies, impedance control, kinematic redundancy, optimization, intermittency, contact tasks and tool use. Students taking the graduate version will complete additional assignments.
N. Hogan


left arrow|2.000-2.199|2.20-2.7999|2.80-2.999 plus Thesis, UROP, UPOP|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 2: Mechanical Engineering
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Course 2: Mechanical Engineering
Fall 2016


Fluid Mechanics and Combustion

2.20 Marine Hydrodynamics
______

Graduate (Fall)
Prereq: 1.060B, 2.006, 2.06, or 2.016
Units: 4-1-7
Lecture: TR1-2.30 (1-246) Recitation: W11 (1-379) or W1 (1-371) or W4 (1-132) +final
______
The fundamentals of fluid mechanics are developed in the context of naval architecture and ocean science and engineering. Transport theorem and conservation principles. Navier-Stokes' equation. Dimensional analysis. Ideal and potential flows. Vorticity and Kelvin's theorem. Hydrodynamic forces in potential flow, D'Alembert's paradox, added-mass, slender-body theory. Viscous-fluid flow, laminar and turbulent boundary layers. Model testing, scaling laws. Application of potential theory to surface waves, energy transport, wave/body forces. Linearized theory of lifting surfaces. Experimental project in the towing tank or propeller tunnel.
D. K. P. Yue
Textbooks (Fall 2016)

2.22 Design Principles for Ocean Vehicles
______

Graduate (Spring)
Prereq: 2.20
Units: 3-3-6
______
Design tools for analysis of linear systems and random processes related to ocean vehicles; description of ocean environment including random waves, ocean wave spectra and their selection; short and long term wave statistics; and ocean currents. Advanced hydrodynamics for design of ocean vehicles and offshore structures including wave forces on towed and moored structures; inertia vs. drag dominated flows; vortex induced vibrations of offshore structures; ship seakeeping and sensitivity of seakeeping performance. Design exercises in application of principles. Several laboratory exercises emphasizing modern measurement techniques, model testing, and flow diagnostic tools.
M. S. Triantafyllou

2.23 Hydrofoils and Propellers
______

Not offered academic year 2017-2018Graduate (Fall); first half of term
Prereq: 2.20, 18.085
Units: 2-0-4
Ends Oct 21. Lecture: MW3.30-5 (1-134) Recitation: T4 (1-132)
______
Reviews the theory and design of hydrofoil sections; lifting and thickness problems for sub-cavitating sections and unsteady flow problems. Covers lifting line and lifting surface theory with applications to hydrofoil craft, rudder, control surface, propeller and wind turbine rotor design. Topics include propeller lifting line and lifting surface theory; wake adapted propellers, steady and unsteady propeller thrust and torque; waterjets; performance analysis and design of wind turbine rotors. Presents numerical principles of vortex lattice and lifting surface panel methods. Projects illustrate the development of theoretical and computational methods for lifting, propulsion and wind turbine applications.
P. D. Sclavounos
No required or recommended textbooks

2.24[J] Ocean Wave Interaction with Ships and Offshore Energy Systems
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as1.692[J])
Prereq: 2.20, 18.085
Units: 4-0-8
______
Surface wave theory, conservation laws and boundary conditions, properties of regular surface waves and random ocean waves. Linearized theory of floating body dynamics, kinematic and dynamic free surface conditions, body boundary conditions. Simple harmonic motions. Diffraction and radiation problems, added mass and damping matrices. General reciprocity identities on diffraction and radiation. Ship wave resistance theory, Kelvin wake physics, ship seakeeping in regular and random waves. Discusses point wave energy absorbers, beam sea and head-sea devises, oscillating water column device and Well's turbine. Discusses offshore floating energy systems and their interaction with ambient waves, current and wind, including oil and gas platforms, liquefied natural gas (LNG) vessels and floating wind turbines. Homework drawn from real-world applications.
P. D. Sclavounos

2.25 Fluid Mechanics
______

Graduate (Fall)
Prereq: 2.006 or 2.06;Coreq: 18.075 or 18.085
Units: 4-0-8
URL: http://web.mit.edu/2.25/www/
Lecture: TR11-12.30 (3-270) Recitation: W11 (1-135) or R3 (1-242) or R4 (1-242) +final
______
Survey of principal concepts and methods of fluid dynamics. Mass conservation, momentum, and energy equations for continua. Navier-Stokes equation for viscous flows. Similarity and dimensional analysis. Lubrication theory. Boundary layers and separation. Circulation and vorticity theorems. Potential flow. Introduction to turbulence. Lift and drag. Surface tension and surface tension driven flows.
A. F. Ghoniem, A. E. Hosoi, G. H. McKinley, A. T. Patera
Textbooks (Fall 2016)

2.26[J] Advanced Fluid Dynamics
______

Graduate (Spring)
(Same subject as1.63[J])
Prereq: 18.085; 2.25 or permission of instructor.
Units: 4-0-8
URL: http://web.mit.edu/2.26/www/index.html
______
Fundamentals of fluid dynamics intrinsic to natural physical phenomena and/or engineering processes. Discusses a range of topics and advanced problem-solving techniques. Sample topics include brief review of basic laws of fluid motion, scaling and approximations, creeping flows, boundary layers in high-speed flows, steady and transient, similarity method of solution, buoyancy-driven convection in porous media, dispersion in steady or oscillatory flows, physics and mathematics of linearized instability, effects of shear and stratification. In alternate years, two of the following modules will be offered: I: Geophysical Fluid Dynamics of Coastal Waters, II: Capillary Phenomena, III: Non-Newtonian Fluids, IV: Flagellar Swimming.
T. R. Akylas, G. H. McKinley, R. Stocker

2.27 Turbulent and Separated Flows
______

Graduate (Spring)
Prereq: 2.20 or 2.25; 18.075
Units: 3-0-9
______
Governing equations, and statistical and dynamical theories of turbulence. Isotropic homogeneous turbulence, near wall turbulence, effects of free surface and surfactants and moving body boundary. Direct numerical simulations, large eddy simulations and sub-grid scale modeling, Reynolds-Average Navier-Stokes (RANS) equations and RANS turbulence models. Flow instability and transitions, almost parallel flows and inviscid and viscous instabilities. Laminar and turbulent separation, expansion flows, separated flows past bluff and streamlined bodies; flow induced vibrations.
D. Yue, A. Techet

2.28 Fundamentals and Applications of Combustion
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 2.006, or 2.051 and 2.06
Units: 3-0-9
______
Fundamentals and modeling of reacting gas dynamics and combustion using analytical and numerical methods. Conservation equations of reacting flows. Multi-species transport, chemical thermodynamics and chemical kinetics. Non-equilibrium flow. Detonation and reacting boundary layers. Ignition, flammability, and extinction. Premixed and diffusion flames. Combustion instabilities. Supersonic combustion. Turbulent combustion. Liquid and solid burning. Fire, safety, and environmental impact. Applications to power and propulsion.
A. F. Ghoniem

2.29 Numerical Fluid Mechanics
______

Graduate (Spring)
Prereq: 2.006, 2.06, 2.016, 2.20, or 2.25; 18.075
Units: 4-0-8
______
Introduction to numerical methods and MATLAB: errors, condition numbers and roots of equations. Navier-Stokes. Direct and iterative methods for linear systems. Finite differences for elliptic, parabolic and hyperbolic equations. Fourier decomposition, error analysis and stability. High-order and compact finite-differences. Finite volume methods. Time marching methods. Navier-Stokes solvers. Grid generation. Finite volumes on complex geometries. Finite element methods. Spectral methods. Boundary element and panel methods. Turbulent flows. Boundary layers. Lagrangian Coherent Structures. Includes a final research project.
P. F. J. Lermusiaux

2.341[J] Macromolecular Hydrodynamics
______

Graduate (Spring)
(Same subject as10.531[J])
Prereq: 2.25, 10.301, or permission of instructor
Units: 3-0-6
______
Physical phenomena in polymeric liquids undergoing deformation and flow. Kinematics and material functions for complex fluids; techniques of viscometry, rheometry; and linear viscoelastic measurements for polymeric fluids. Generalized Newtonian fluids. Continuum mechnanics, frame invariance, and convected derivatives for finite strain viscoelasticity. Differential and integral constitutive equations for viscoelastic fluids. Analytical solutions to isothermal and non-isothermal flow problems; the roles of non-Newtonian viscosity, linear viscoelasticity, normal stresses, elastic recoil, stress relaxation in processing flows. Introduction to molecular theories for dynamics of polymeric fluids. (Extensive class project and presentation required instead of a final exam).
R. C. Armstrong, G. H. McKinley

MEMS and Nanotechnology

2.37 Fundamentals of Nanoengineering
______

Graduate (Spring)
(Subject meets with2.370)
Prereq: Permission of instructor
Units: 3-0-9
______

2.370 Fundamentals of Nanoengineering
______

Undergrad (Spring)
(Subject meets with2.37)
Prereq: 2.001; Chemistry (GIR)
Units: 3-0-9
______
Presents the fundamentals of molecular modeling in engineering in the context of nanoscale mechanical engineering applications. Statistical mechanics and its connection to engineering thermodynamics. Molecular origin and limitations of macroscopic descriptions and constitutive relations for equilibrium and non-equilibrium behavior. Introduction to molecular simulation, solid-state physics and electrokinetic phenomena. Discusses molecular approaches to modern nanoscale engineering problems. Graduate students are required to complete additional assignments with stronger analytical content.
N. G. Hadjiconstantinou

2.372[J] Design and Fabrication of Microelectromechanical Systems
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as6.777[J])
(Subject meets with2.374[J],6.717[J])
Prereq: 6.003 or 2.003, Physics II (GIR); or permission of instructor
Units: 3-0-9
______

2.374[J] Design and Fabrication of Microelectromechanical Systems
______

Not offered academic year 2016-2017Undergrad (Spring)
(Same subject as6.717[J])
(Subject meets with2.372[J],6.777[J])
Prereq: 6.003 or 2.003, Physics II (GIR); or permission of instructor
Units: 3-0-9
______
Provides an introduction to microsystem design. Covers material properties, microfabrication technologies, structural behavior, sensing methods, electromechanical actuation, thermal actuation and control, multi-domain modeling, noise, and microsystem packaging. Applies microsystem modeling, and manufacturing principles to the design and analysis a variety of microscale sensors and actuators (e.g., optical MEMS, bioMEMS, and inertial sensors). Emphasizes modeling and simulation in the design process. Students taking the graduate version complete additional assignments.
Staff

2.391[J] Nanostructure Fabrication
______

Graduate (Spring)
(Same subject as6.781[J])
Prereq: 6.152, 6.161, or 2.710; or permission of instructor
Units: 4-0-8
______
Describes current techniques used to analyze and fabricate nanometer-length-scale structures and devices. Emphasizes imaging and patterning of nanostructures, including fundamentals of optical, electron (scanning, transmission, and tunneling), and atomic-force microscopy; optical, electron, ion, and nanoimprint lithography, templated self-assembly, and resist technology. Surveys substrate characterization and preparation, facilities, and metrology requirements for nanolithography. Addresses nanodevice processing methods, such as liquid and plasma etching, lift-off, electroplating, and ion-implant. Discusses applications in nanoelectronics, nanomaterials, and nanophotonics.
K. K. Berggren

Thermodynamics

2.42 General Thermodynamics
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR12.30-2 (3-333) +final
______
General foundations of thermodynamics from an entropy point of view, entropy generation and transfer in complex systems. Definitions of work, energy, stable equilibrium, available energy, entropy, thermodynamic potential, and interactions other than work (nonwork, heat, mass transfer). Applications to properties of materials, bulk flow, energy conversion, chemical equilibrium, combustion, and industrial manufacturing.
J. Brisson
No required or recommended textbooks

Heat and Mass Transfer

2.500 Desalination and Water Purification
______

Graduate (Spring)
Prereq: 1.020, 2.006, 10.302, or 2.051 and 2.06, or permission of instructor
Units: 3-0-9
______
Introduces the fundamental science and technology of desalinating water to overcome water scarcity and ensure sustainable water supplies. Covers basic water chemistry, flash evaporation, reverse osmosis and membrane engineering, electrodialysis, nanofiltration, solar desalination, energy efficiency of desalination systems, fouling and scaling, environmental impacts, and economics of desalination systems. Open to upper-class undergraduates.
J. H. Lienhard, M. Balaban

2.51 Intermediate Heat and Mass Transfer
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 2.006, or 2.051 and 2.06, or permission of instructor
Units: 3-0-9
______
Analysis, modeling, and design of heat and mass transfer processes with application to common technologies. Unsteady heat conduction in one or more dimensions, steady conduction in multidimensional configurations, numerical simulation; forced convection in laminar and turbulent flows; natural convection in internal and external configurations; phase change heat transfer; thermal radiation, black bodies, grey radiation networks, spectral and solar radiation; mass transfer at low rates, evaporation.
J. H. Lienhard, E. N. Wang

2.52[J] Modeling and Approximation of Thermal Processes
______

Graduate (Fall)
(Same subject as4.424[J])
Prereq: 2.51
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4424
Lecture: MW12.30-2 (5-217)
______
Provides instruction on how to model thermal transport processes in typical engineering systems such as those found in manufacturing, machinery, and energy technologies. Successive modules cover basic modeling tactics for particular modes of transport, including steady and unsteady heat conduction, convection, multiphase flow processes, and thermal radiation. Includes a creative design project executed by the students.
L. R. Glicksman
Textbooks (Fall 2016)

2.55 Advanced Heat and Mass Transfer
______

Graduate (Spring)
Prereq: 2.51
Units: 4-0-8
URL: http://web.mit.edu/2.55/www/
______
Advanced treatment of fundamental aspects of heat and mass transport. Covers topics such as diffusion kinetics, conservation laws, laminar and turbulent convection, mass transfer including phase change or heterogeneous reactions, and basic thermal radiation. Problems and examples include theory and applications drawn from a spectrum of engineering design and manufacturing problems.
J. H. Lienhard

2.56 Conduction and Change of Phase Heat Transfer
______

Graduate (Spring)
Prereq: 2.51,Coreq: 18.075
Units: 3-0-9
______
Solutions of steady and transient heat conduction problems with various boundary conditions. Approximate methods: application of numerical techniques. Moving boundaries: problems in freezing and melting. Condensation heat transfer. Boiling: mechanisms and heat transfer correlations. Thermal modeling of engineering systems: thermal contact resistance; heat and mass transfer in material processing; heat transfer in biomedical systems.
J. H. Lienhard

2.57 Nano-to-Macro Transport Processes
______

Graduate (Spring)
Not offered regularly; consult department
(Subject meets with2.570)
Prereq: 2.005, 2.051, or permission of instructor
Units: 3-0-9
______

2.570 Nano-to-Macro Transport Processes
______

Undergrad (Spring)
Not offered regularly; consult department
(Subject meets with2.57)
Prereq: 2.005, 2.051, or permission of instructor
Units: 3-0-9
______
Parallel treatments of photons, electrons, phonons, and molecules as energy carriers; aiming at a fundamental understanding of descriptive tools for energy and heat transport processes, from nanoscale to macroscale. Topics include energy levels; statistical behavior and internal energy; energy transport in the forms of waves and particles; scattering and heat generation processes; Boltzmann equation and derivation of classical laws; and deviation from classical laws at nanoscale and their appropriate descriptions. Applications in nanotechnology and microtechnology. Students taking the graduate version complete additional assignments.
G. Chen

2.59[J] Thermal Hydraulics in Power Technology
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as10.536[J],22.313[J])
Prereq: 2.006, 10.302, 22.312, or permission of instructor
Units: 3-2-7
______
Emphasis on thermo-fluid dynamic phenomena and analysis methods for conventional and nuclear power stations. Kinematics and dynamics of two-phase flows. Steam separation. Boiling, instabilities, and critical conditions. Single-channel transient analysis. Multiple channels connected at plena. Loop analysis including single and two-phase natural circulation. Subchannel analysis.
E. Baglietto

Energy and Power Systems

2.60[J] Fundamentals of Advanced Energy Conversion
______

Undergrad (Spring)
(Same subject as10.390[J])
(Subject meets with2.62[J],10.392[J],22.40[J])
Prereq: 2.006, or 2.051 and 2.06, or permission of instructor
Units: 4-0-8
______
Fundamentals of thermodynamics, chemistry, and transport applied to energy systems. Analysis of energy conversion and storage in thermal, mechanical, chemical, and electrochemical processes in power and transportation systems, with emphasis on efficiency, performance, and environmental impact. Applications to fuel reforming and alternative fuels, hydrogen, fuel cells and batteries, combustion, catalysis, combined and hybrid power cycles using fossil, nuclear and renewable resources. CO2 separation and capture. Biomass energy. Students taking graduate version complete additional assignments.
A. F. Ghoniem, W. Green

2.61 Internal Combustion Engines
______

Graduate (Spring)
Prereq: 2.006
Units: 3-1-8
URL: http://web.mit.edu/2.61/www/index.html
______
Fundamentals of how the design and operation of internal combustion engines affect their performance, efficiency, fuel requirements, and environmental impact. Study of fluid flow, thermodynamics, combustion, heat transfer and friction phenomena, and fuel properties, relevant to engine power, efficiency, and emissions. Examination of design features and operating characteristics of different types of internal combustion engines: spark-ignition, diesel, stratified-charge, and mixed-cycle engines. Engine Laboratory project. For graduate and senior undergraduate students.
W. K. Cheng

2.611 Marine Power and Propulsion
______

Graduate (Fall)
(Subject meets with2.612)
Prereq: 2.005
Units: 4-0-8
Lecture: TR9.30-11 (5-217) Recitation: F10 (5-217)
______
Textbooks (Fall 2016)

2.612 Marine Power and Propulsion
______

Undergrad (Fall)
(Subject meets with2.611)
Prereq: 2.005
Units: 4-0-8
Lecture: TR9.30-11 (5-217) Recitation: F10 (5-217)
______
Selection and evaluation of commercial and naval ship power and propulsion systems. Analysis of propulsors, prime mover thermodynamic cycles, propeller-engine matching. Propeller selection, waterjet analysis, review of alternative propulsors; thermodynamic analyses of Rankine, Brayton, Diesel, and Combined cycles, reduction gears and integrated electric drive. Battery operated vehicles, fuel cells. Term project requires analysis of alternatives in propulsion plant design for given physical, performance, and economic constraints. Graduate students complete different assignments and exams.
J. Harbour, M. S. Triantafyllou, R. S. McCord
Textbooks (Fall 2016)

2.62[J] Fundamentals of Advanced Energy Conversion
______

Graduate (Spring)
(Same subject as10.392[J],22.40[J])
(Subject meets with2.60[J],10.390[J])
Prereq: 2.006, or 2.051 and 2.06, or permission of instructor
Units: 4-0-8
______
Fundamentals of thermodynamics, chemistry, and transport applied to energy systems. Analysis of energy conversion and storage in thermal, mechanical, chemical, and electrochemical processes in power and transportation systems, with emphasis on efficiency, performance and environmental impact. Applications to fuel reforming and alternative fuels, hydrogen, fuel cells and batteries, combustion, catalysis, combined and hybrid power cycles using fossil, nuclear and renewable resources. CO2 separation and capture. Biomass energy. Meets with 2.60 when offered concurrently; students taking the graduate version complete additional assignments.
A. F. Ghoniem, W. Green

2.625[J] Electrochemical Energy Conversion and Storage: Fundamentals, Materials and Applications
______

Graduate (Fall)
(Same subject as10.625[J])
Prereq: 2.005, 3.046, 3.53, 10.40, or 2.051 and 2.06, or permission of instructor
Units: 4-0-8
Lecture: TR2.30-4 (3-333) Recitation: W4 (1-150)
______
Fundamental concepts, tools, and applications in electrochemical science and engineering. Introduces thermodynamics, kinetics and transport of electrochemical reactions. Describes how materials structure and properties affect electrochemical behavior of particular applications, for instance in lithium rechargeable batteries, electrochemical capacitors, fuel cells, photo electrochemical cells, and electrolytic cells. Discusses state-of-the-art electrochemical energy technologies for portable electronic devices, hybrid and plug-in vehicles, electrical vehicles. Theoretical and experimental exploration of electrochemical measurement techniques in cell testing, and in bulk and interfacial transport measurements (electronic and ionic resistivity and charge transfer cross the electrode-electrolyte interface).
Y. Shao-Horn
No textbook information available

2.626 Fundamentals of Photovoltaics
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with2.627)
Prereq: Permission of instructor
Units: 4-0-8
______

2.627 Fundamentals of Photovoltaics
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with2.626)
Prereq: Permission of instructor
Units: 4-0-8
______
Fundamentals of photoelectric conversion: charge excitation, conduction, separation, and collection. Studies commercial and emerging photovoltaic technologies. Cross-cutting themes include conversion efficiencies, loss mechanisms, characterization, manufacturing, systems, reliability, life-cycle analysis, and risk analysis. Photovoltaic technology evolution in the context of markets, policies, society, and environment. Graduate students complete additional work.
T. Buonassisi

2.64 Superconducting Magnets
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: 2.51, permission of instructor
Units: 3-0-9
______
Covers design, manufacture, and operation issues of superconducting magnets for major engineering applications in biomedical science (MRI & NMR magnets), high-energy physics (dipole/quadrupole/detector magnets), and electric power (motor/generator/transmission cable) as well as laboratory use. Topics include electromagnetic field analyses, mechanical stress analyses, thermal stability analyses, protection circuit design, cryogenics, and experimental techniques.
Y. Iwasa, S. Hahn

2.65[J] Sustainable Energy
______

Graduate (Fall)
(Same subject as1.818[J],10.391[J],11.371[J],22.811[J])
(Subject meets with2.650[J],10.291[J],22.081[J])
Prereq: Permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/10.391J/www/
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various energy technologies in each fuel cycle stage for fossil (oil, gas, synthetic), nuclear (fission and fusion) and renewable (solar, biomass, wind, hydro, and geothermal) energy types, along with storage, transmission, and conservation issues. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments.
M. W. Golay
Textbooks (Fall 2016)

2.650[J] Introduction to Sustainable Energy
______

Undergrad (Fall)
(Same subject as10.291[J],22.081[J])
(Subject meets with1.818[J],2.65[J],10.391[J],11.371[J],22.811[J])
Prereq: Permission of instructor
Units: 3-1-8
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various renewable and conventional energy production technologies, energy end-use practices and alternatives, and consumption practices in different countries. Investigates their attributes within a quantitative analytical framework for evaluation of energy technology system proposals. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments. Limited to juniors and seniors.
M. W. Golay
Textbooks (Fall 2016)

2.651[J] D-Lab: Energy
______

Undergrad (Spring)
(Same subject asEC.711[J])
(Subject meets withEC.791)
Prereq: None
Units: 3-3-6
______
Provides a project-based approach that engages students in understanding and addressing the applications of alternative energy technology in developing countries. Focuses on compact, robust, low-cost systems for generating electrical power. Includes projects such as micro-hydro, solar, or wind turbine generators along with theoretical analysis, design, prototype construction, evaluation and implementation. Students will have the opportunity for an optional spring break site visit to identify and implement projects. Students taking graduate version complete additional assignments. Enrollment limited by lottery; must attend first class session.
S. L. Hsu

2.66[J] Fundamentals of Energy in Buildings
______

Not offered academic year 2016-2017Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject as1.044[J],4.42[J])
Prereq: Physics I (GIR), Calculus II (GIR)
Units: 3-2-7
______
Design-based introduction to energy and thermo-sciences, with applications to sustainable, energy-efficient architecture and building technology. Covers introductory thermodynamics, air/water/vapor mixtures, and heat transfer. Studies leading order factors in building energy use. Includes several building design projects in which students creatively employ energy fundamentals and building energy use.
L. R. Glicksman

Experimental Engineering

2.670 Mechanical Engineering Tools
______

Undergrad (IAP)
Prereq: None
Units: 0-1-2
______
Introduces the fundamentals of machine tools use and fabrication techniques. Students work with a variety of machine tools including the bandsaw, milling machine, and lathe. Mechanical Engineering students are advised to take this subject in the first IAP after declaring their major. Enrollment may be limited due to laboratory capacity. Preference to Course 2 majors and minors.
M. Culpepper

2.671 Measurement and Instrumentation
______

Undergrad (Fall, Spring) Institute Lab
Prereq: 2.001; 2.003 or 2.03; 2.086; Physics II (GIR)
Units: 3-3-6
URL: http://web.mit.edu/2.671/www/
Pre-reg required. Lecture: TR12.30-2 (3-270) Lab: M2-5 (3-038) or T9-12 (3-038) or T2-5 (3-038) or R9-12 (3-038) or R2-5 (3-038) or F9-12 (3-038) or F1.30-4.30 (3-038)
______
Experimental techniques for observation and measurement of physical variables such as force, strain, temperature, flow rate, and acceleration. Emphasizes principles of transduction, measurement circuitry, MEMS sensors, Fourier transforms, linear and nonlinear function fitting, uncertainty analysis, probability density functions and statistics, system identification, electrical impedance analysis and transfer functions, computer-aided experimentation, and technical reporting. Typical laboratory experiments involve oscilloscopes, electronic circuits including operational amplifiers, thermocouples, strain gauges, digital recorders, lasers, etc. Basic material and lab objectives are developed in lectures. Instruction and practice in oral and written communication provided. Enrollment limited.
I. W. Hunter, J. J. Leonard
No required or recommended textbooks

2.673[J] Instrumentation and Measurement for Biological Systems
______

Undergrad (Fall, Spring)
(Same subject as20.309[J])
(Subject meets with20.409)
Prereq: Biology (GIR), Physics II (GIR), 6.0002, 18.03; or permission of instructor
Units: 3-6-3
Lecture: TR12 (32-155) Recitation: F12 (56-114)
______
Sensing and measurement aimed at quantitative molecular/cell/tissue analysis in terms of genetic, biochemical, and biophysical properties. Methods include light and fluorescence microscopies, and electro-mechanical probes (atomic force microscopy, optical traps, MEMS devices). Application of statistics, probability, signal and noise analysis, and Fourier techniques to experimental data. Enrollment limited; preference to Course 20 undergraduates.
Fall:P. Blainey, S. Manalis, E. Frank, S. Wasserman, J. Bagnall
Spring:E. Boyden, P. So, S. Wasserman, J. Bagnall, E. Frank
No textbook information available

2.674 Micro/Nano Engineering Laboratory
______

Undergrad (Fall, Spring)
Prereq: 2.001; 2.003 or 2.03; 2.671;Coreq: 2.005, or 2.051 and 2.06; or permission of instructor
Units: 1-3-2
Lecture: T11 (35-225) Lab: R9-12 (5-026) or R1-4 (5-026) or F9-12 (5-026) or F1-4 (5-026) +final
______
Concepts, ideas, and enabling tools of nanoengineering taught through lab modules and imaging tools, which include microfluidics, microthermal systems, MEMS, nanomaterials, SEM, TEM, and AFM. Provides practical knowledge and experience via building, observing and manipulating micro- and nanoscale structures. Teaches students how to apply engineering knowledge to practical fluid, thermal, and dynamic systems at small scales. Meets with 2.675 in the fall term. Enrollment limited; preference to Course 2 majors and minors.
S. G. Kim, G. Chen, E. Wang, R. Karnik
No required or recommended textbooks

2.675 Micro/Nano Engineering Laboratory
______

Graduate (Fall)
Prereq: 2.25; 2.372 or permission of instructor
Units: 2-3-7
Lecture: T11 (35-225) Lab: R9-12 (5-026) or R1-4 (5-026) or F9-12 (5-026) or F1-4 (5-026) Recitation: T12 (37-212) +final
______
Concepts, ideas, and enabling tools of nanoengineering taught through lab modules and imaging tools, which include microfluidics, microthermal systems, MEMS, nanomaterials, SEM, TEM, and AFM. Provides practical knowledge and experience via building, observing and manipulating micro- and nanoscale structures. Teaches students how to apply engineering knowledge to practical fluid, thermal, and dynamic systems at small scales. Meets with 2.674 in the fall term. Enrollment limited.
S. G. Kim, G. Chen, E. Wang, R. Karnik
No required or recommended textbooks

2.678 Electronics for Mechanical Systems
______

Undergrad (Fall, Spring)
Prereq: Physics II (GIR)
Units: 2-2-2
Lecture: MW11 (3-270) Lab: W12.30-2.30 (3-062) or W3-5 (3-062) or R12.30-2.30 (3-062) or R3-5 (3-062) or F11-1 (3-062) or F2-4 (3-062)
______
Practical introduction to the fundamentals of electronics in the context of electro-mechanical systems, with emphasis on experimentation and project work in basic electronics. Laboratory exercises include the design and construction of simple electronic devices, such as power supplies, amplifiers, op-amp circuits, switched mode dc-dc converters, and dc motor drivers. Surveys embedded microcontrollers as system elements. Laboratory sessions stress the understanding of electronic circuits at the component level, but also point out the modern approach of system integration using commercial modules and specialized integrated circuits. Enrollment may be limited due to laboratory capacity; preference to Course 2 majors and minors.
D. Rowell
No required or recommended textbooks

Oceanographic Engineering and Acoustics

2.680 Unmanned Marine Vehicle Autonomy, Sensing, and Communication
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 2-6-4
______
Focuses on software and algorithms for autonomous decision making (autonomy) by underwater vehicles operating in ocean environments. Discusses how autonomous marine vehicles (UMVs) adapt to the environment for improved sensing performance. Covers sensors for acoustic, biological and chemical sensing and their integration with the autonomy system for environmentally adaptive undersea mapping and observation. Introduces students to the underwater acoustic communication environment and various options for undersea navigation, highlighting their relevance to the operation of collaborative undersea networks for environmental sensing. Labs involve the use of the MOOP-IvP autonomy software for the development of integrated sensing, modeling and control solutions. Solutions modeled in simulation environments and include field tests with small autonomous surface and underwater vehicles operated on the Charles River. Limited enrollment.
H. Schmidt, J.J. Leonard, M. Benjamin

2.681 Environmental Ocean Acoustics
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 2.066, 18.075 or permission of instructor
Units: 3-0-9
______
Fundamentals of underwater sound, and its application to mapping and surveillance in an ocean environment. Wave equations for fluid and elastic media. Reflection and transmission of sound at plane interfaces. Wave theory representation of acoustic source radiation and propagation in shallow and deep ocean waveguides. Interaction of underwater sound with elastic waves in the seabed and an Arctic ice cover, including effects of porosity and anisotropy. Numerical modeling of the propagation of underwater sound, including spectral methods, normal mode theory, and the parabolic equation method, for laterally homogeneous and inhomogeneous environments. Doppler effects. Effects of oceanographic variability and fluctuation - spatial and temporal coherence. Generation and propagation of ocean ambient noise. Modeling and simulation of signals and noise in traditional sonar systems, as well as modern, distributed, autonomous acoustic surveillance systems.
H. Schmidt

2.682 Acoustical Oceanography
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: 2.681
Units: 3-0-9
______
Provides brief overview of what important current research topics are in oceanography (physical, geological, and biological) and how acoustics can be used as a tool to address them. Three typical examples are climate, bottom geology, and marine mammal behavior. Addresses the acoustic inverse problem, reviewing inverse methods (linear and nonlinear) and the combination of acoustical methods with other measurements as an integrated system. Concentrates on specific case studies, taken from current research journals.
J. F. Lynch, Woods Hole Staff

2.683 Marine Bioacoustics and Geoacoustics
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: 2.681
Units: 3-0-9
______
Both active and passive acoustic methods of measuring marine organisms, the seafloor, and their interactions are reviewed. Acoustic methods of detecting, observing, and quantifying marine biological organisms are described, as are acoustic methods of measuring geological properties of the seafloor, including depth, and surficial and volumetric composition. Interactions are also described, including effects of biological scatterers on geological measurements, and effects of seafloor scattering on measurements of biological scatterers on, in, or immediately above the seafloor. Methods of determining small-scale material properties of organisms and the seafloor are outlined. Operational methods are emphasized, and corresponding measurement theory is described. Case studies are used in illustration. Principles of acoustic-system calibration are elaborated.
K. G. Foote, Woods Hole Staff

2.684 Wave Scattering by Rough Surfaces and Inhomogeneous Media
______

Not offered academic year 2017-2018Graduate (Spring) Can be repeated for credit
Prereq: 2.066 or permission of instrctor
Units: 3-0-9
______
An advanced-level subject designed to give students a working knowledge of current techniques in this area. Material is presented principally in the context of ocean acoustics, but can be used in other acoustic and electromagnetic applications. Includes fundamentals of wave propagation through, and/or scattering by: random media, extended coherent structures, rough surfaces, and discrete scatterers.
T. K. Stanton, A. C. Lavery, Woods Hole Staff

2.687 Time Series Analysis and System Identification
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: 6.011, 18.06
Units: 3-0-9
______
Covers matched filtering, power spectral (PSD) estimation, and adaptive signal processing / system identification algorithms. Algorithm development is framed as an optimization problem, and optimal and approximate solutions are described. Reviews time-varying systems, first and second moment representations of stochastic processes, and state-space models. Also covers algorithm derivation, performance analysis, and robustness to modeling errors. Algorithms for PSD estimation, the LMS and RLS algorithms, and the Kalman Filter are treated in detail.
J. C. Preisig, Woods Hole Staff

2.688 Principles of Oceanographic Instrument Systems -- Sensors and Measurements
______

Graduate (Fall)
Prereq: 18.075, 2.671
Units: 3-3-6
Meets at WHOI. TBA.
______
Introduces theoretical and practical principles of design of oceanographic sensor systems. Transducer characteristics for acoustic, current, temperature, pressure, electric, magnetic, gravity, salinity, velocity, heat flow, and optical devices. Limitations on these devices imposed by ocean environment. Signal conditioning and recording; noise, sensitivity, and sampling limitations; standards. Principles of state-of-the-art systems being used in physical oceanography, geophysics, submersibles, acoustics discussed in lectures by experts in these areas. Day cruises in local waters during which the students will prepare, deploy and analyze observations from standard oceanographic instruments constitute the lab work for this subject.
H. Singh, R. Geyer, A. Michel
No textbook information available

2.689[J] Projects in Oceanographic Engineering
______

Graduate (Fall, Summer) Can be repeated for credit
(Same subject as 1.699[J])
Prereq: Permission of instructor
Units arranged [P/D/F]
Meets at WHOI. TBA.
______
Projects in oceanographic engineering, carried out under supervision of Woods Hole Oceanographic Institution staff. Given at Woods Hole Oceanographic Institution.
J. Preisig, Woods Hole Staff
No textbook information available

2.690 Corrosion in Marine Engineering
______

Graduate (Summer)
Prereq: 3.012, permission of instructor
Units: 3-0-3
______
Introduction to forms of corrosion encountered in marine systems material selection, coatings and protection systems. Case studies and causal analysis developed through student presentations.
J. Page, T. Eagar
No textbook information available
______
Summer 2016 Description for Corrosion in Marine Engineering
Prereq:3.012, permission of instructor
Units: 3-0-3


Introduction to forms of corrosion encountered in marine systems material selection, coatings and protection systems. Case studies and causal analysis developed through student presentations.

T. Eager
Section: MTWThF 8:00 AM-10:00 AM Room 4-145 From 06-JUN-16 Thru 22-JUL-16
No textbook information available

Naval Architecture

2.700 Principles of Naval Architecture
______

Undergrad (Fall)
(Subject meets with2.701)
Prereq: 2.002
Units: 4-2-6
Lecture: MW9.30-11 (5-217) Recitation: F1 (5-217)
______
F. S. Hover, A. H. Techet, J. Harbour, P. D. Sclavounos, J. Page
Textbooks (Fall 2016)

2.701 Principles of Naval Architecture
______

Graduate (Fall)
(Subject meets with2.700)
Prereq: 2.002
Units: 4-2-6
Lecture: MW9.30-11 (5-217) Recitation: F1 (5-217)
______
Presents principles of naval architecture, ship geometry, hydrostatics, calculation and drawing of curves of form, intact and damage stability, hull structure strength calculations and ship resistance. Introduces computer-aided naval ship design and analysis tools. Projects include analysis of ship lines drawings, calculation of ship hydrostatic characteristics, analysis of intact and damaged stability, ship model testing, and hull structure strength calculations. Students taking graduate version complete additional assignments.
J. Harbour, S. Brizzolara, J. Page
Textbooks (Fall 2016)

2.702 Systems Engineering and Naval Ship Design
______

Graduate (Spring)
Prereq: 2.701
Units: 3-3-3
______
Introduces principles of systems engineering and ship design with an overview of naval ship design and acquisition processes, requirements setting, formulation of a systematic plan, design philosophy and constraints, formal decision making methods, selection criteria, optimization, variant analysis, trade-offs, analysis of ship design trends, risk, and cost analysis. Emphasizes the application of principles through completion of a design exercise and project.
J. Harbour, J. Page

2.703 Principles of Naval Ship Design
______

Graduate (Fall)
Prereq: 2.082, 2.20, 2.611, 2.702
Units: 4-2-6
Lecture: TR11-12.30 (5-217)
______
Covers the design of surface ship platforms for naval applications. Includes topics such as hull form selection and concept design synthesis, topside and general arrangements, weight estimation, and technical feasibility analyses (including strength, stability, seakeeping, and survivability.). Practical exercises involve application of design principles and utilization of advanced computer-aided ship design tools.
J. Harbour, J. Page
No required or recommended textbooks

2.704 Projects in Naval Ship Conversion Design
______

Graduate (IAP, Spring)
Prereq: 2.703
Units: 1-6-5
______
Focuses on conversion design of a naval ship. A new mission requirement is defined, requiring significant modification to an existing ship. Involves requirements setting, design plan formulation and design philosophy, and employs formal decision-making methods. Technical aspects demonstrate feasibility and desirability. Includes formal written and verbal reports and team projects.
J. Harbour, J. Page
No textbook information available

2.705 Projects in New Concept Naval Ship Design
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 2.704
Units arranged
TBA.
______
Focus on preliminary design of a new naval ship, fulfilling a given set of mission requirements. Design plan formulation, system level trade-off studies, emphasizes achieving a balanced design and total system integration. Formal written and oral reports. Team projects extend over three terms.
J. Harbour, J. Page
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

2.707 Submarine Structural Acoustics
______

Graduate (Spring); first half of term
Prereq: 2.066
Units: 2-0-4
______
Introduction to the acoustic interaction of submerged structures with the surrounding fluid. Fluid and elastic wave equations. Elastic waves in plates. Radiation and scattering from planar structures as well as curved structures such as spheres and cylinders. Acoustic imaging of structural vibrations. Students can take 2.085 in the second half of term.
H. Schmidt

2.708 Traditional Naval Architecture Design
______

Graduate (IAP)
Prereq: None
Units: 2-0-1 [P/D/F]
______
Week-long intensive introduction to traditional design methods in which students hand draw a lines plan of a N. G. Herreshoff (MIT Class of 1870) design based on hull shape offsets taken from his original design model. After completing the plan, students then carve a wooden half-hull model of the boat design. Covers methods used to develop hull shape analysis data from lines plans. Provides students with instruction in safe hand tool use and how to transfer their lines to 3D in the form of their model. Limited to 15.
K. Hasselbalch, J. Harbour

Optics

2.71 Optics
______

Undergrad (Fall)
(Subject meets with2.710)
Prereq: Physics II (GIR); 18.03; 2.004, 2.04A, 2.04B, or permission of instructor
Units: 3-0-9
Lecture: MW9.30-11 (1-135)
______
Textbooks (Fall 2016)

2.710 Optics
______

Graduate (Fall)
(Subject meets with2.71)
Prereq: Physics II (GIR); 18.03; 2.004, 2.04A, 2.04B, or permission of instructor
Units: 3-0-9
Lecture: MW9.30-11 (1-135)
______
Introduction to optical science with elementary engineering applications. Geometrical optics: ray-tracing, aberrations, lens design, apertures and stops, radiometry and photometry. Wave optics: basic electrodynamics, polarization, interference, wave-guiding, Fresnel and Fraunhofer diffraction, image formation, resolution, space-bandwidth product. Emphasis on analytical and numerical tools used in optical design. Graduate students are required to complete additional assignments with stronger analytical content, and an advanced design project.
G. Barbastathis, P. T. So
Textbooks (Fall 2016)

2.715[J] Optical Microscopy and Spectroscopy for Biology and Medicine
______

Graduate (Spring)
Not offered regularly; consult department
(Same subject as20.487[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces the theory and the design of optical microscopy and its applications in biology and medicine. The course starts from an overview of basic optical principles allowing an understanding of microscopic image formation and common contrast modalities such as dark field, phase, and DIC. Advanced microscopy imaging techniques such as total internal reflection, confocal, and multiphoton will also be discussed. Quantitative analysis of biochemical microenvironment using spectroscopic techniques based on fluorescence, second harmonic, Raman signals will be covered. We will also provide an overview of key image processing techniques for microscopic data.
P. T. So, C. Sheppard

2.717 Optical Engineering
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 2.710 or permission of instructor
Units: 3-0-9
______
Theory and practice of optical methods in engineering and system design. Emphasis on diffraction, statistical optics, holography, and imaging. Provides engineering methodology skills necessary to incorporate optical components in systems serving diverse areas such as precision engineering and metrology, bio-imaging, and computing (sensors, data storage, communication in multi-processor systems). Experimental demonstrations and a design project are included.
P. T. So, G. Barbastathis

2.718 Photonic Materials
______

Undergrad (Fall)
(Subject meets with2.719)
Prereq: 2.003, 8.03, 6.161, or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (1-134)
______
Textbooks (Fall 2016)

2.719 Photonic Materials
______

Graduate (Fall)
(Subject meets with2.718)
Prereq: 2.003, 8.03, 6.161, or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (1-134)
______
Provides a review of Maxwell's equations and the Helmholtz wave equation. Optical devices: waveguides and cavities, phase and group velocity, causality, and scattering. Light-matter interaction in bulk, surface, and subwavelength-structured matter. Effective media, dispersion relationships, wavefronts and rays, eikonal description of light propagation, phase singularities. Transformation optics, gradient effective media. Includes description of the experimental tools for realization and measurement of photonic materials and effects. Students taking graduate version complete additional assignments.
G. Barbastathis, N. Fang
Textbooks (Fall 2016)

Design

2.70 FUNdaMENTALS of Precision Product Design
______

Undergrad (Spring)
(Subject meets with2.77)
Prereq: 2.008
Units: 3-3-6
______

2.77 FUNdaMENTALS of Precision Product Design
______

Graduate (Spring)
(Subject meets with2.70)
Prereq: 2.008
Units: 3-3-6
______
Examines design, selection, and combination of machine elements to produce a robust precision system. Introduces process, philosophy and physics-based principles of design to improve/enable renewable power generation, energy efficiency, and manufacturing productivity. Topics include linkages, power transmission, screws and gears, actuators, structures, joints, bearings, error apportionment, and error budgeting. Considers each topic with respect to its physics of operation, mechanics (strength, deformation, thermal effects) and accuracy, repeatability, and resolution. Includes guest lectures from practicing industry and academic leaders. Students design, build, and test a small benchtop precision machine, such as a heliostat for positioning solar PV panels or a two or three axis machine. Prior to each lecture, students review the pre-recorded detailed topic materials and then converge on what parts of the topic they want covered in extra depth in lecture. Students are assessed on their preparation for and participation in class sessions. Students taking graduate version complete additional assignments. Enrollment limited.
A. Slocum

2.72 Elements of Mechanical Design
______

Undergrad (Spring)
(Subject meets with2.720)
Prereq: 2.005 or 2.051; 2.008;Coreq: 2.671
Units: 3-3-6
URL: http://pcsl.mit.edu/2_72/index.html
______
Advanced study of modeling, design, integration, and best practices for use of machine elements, such as bearings, bolts, belts, flexures, and gears. Modeling and analysis is based upon rigorous application of physics, mathematics, and core mechanical engineering principles, which are reinforced via laboratory experiences and a design project in which students model, design, fabricate, and characterize a mechanical system that is relevant to a real-world application. Activities and quizzes are directly related to, and coordinated with, the project deliverables. Develops the ability to synthesize, model and fabricate a design subject to engineering constraints (e.g., cost, time, schedule). Students taking graduate version complete additional assignments. Enrollment limited.
M. L. Culpepper

2.720 Elements of Mechanical Design
______

Graduate (Spring)
(Subject meets with2.72)
Prereq: permission of instructor
Units: 3-3-6
______
Advanced study of modeling, design, integration, and best practices for use of machine elements, such as bearings, bolts, belts, flexures, and gears. Modeling and analysis is based upon rigorous application of physics, mathematics, and core mechanical engineering principles, which are reinforced via laboratory experiences and a design project in which students model, design, fabricate, and characterize a mechanical system that is relevant to a real-world application. Activities and quizzes are directly related to, and coordinated with, the project deliverables. Develops the ability to synthesize, model and fabricate a design subject to engineering constraints (e.g., cost, time, schedule). Students taking graduate version complete additional assignments.
M. L. Culpepper

2.722[J] D-Lab: Design
______

Undergrad (Spring)
(Same subject asEC.720[J])
Prereq: 2.670 or permission of the instructor
Units: 3-0-9
______
Addresses problems faced by underserved communities with a focus on design, experimentation, and prototyping processes. Particular attention placed on constraints faced when designing for developing countries. Multidisciplinary teams work on long-term projects in collaboration with community partners, field practitioners, and experts in relevant fields. Topics covered include design for affordability, manufacture, sustainability, and strategies for working effectively with community partners and customers. Students may continue projects begun in EC.701. Enrollment limited by lottery; must attend first class session.
A. B. Smith, M. McCambridge

2.723 Engineering Innovation and Design
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:2.723,6.902,16.662)
Prereq: None
Units: 3-0-3
Lecture: M EVE (7-9 PM) (32-155) Recitation: M EVE (9 PM) (32-155) or W EVE (7 PM) (2-105) or W EVE (8 PM) (2-105)
______
Project-based seminar in innovative design thinking develops students' ability to conceive, implement, and evaluate successful projects in any engineering discipline. Lectures focus on the iterative design process and techniques to enhance creative analysis. Students use this process to design and implement robust voice recognition applications using a simple web-based system. They also give presentations and receive feedback to sharpen their communication skills for high emotional and intellectual impact. Guest lectures illustrate multidisciplinary approaches to design thinking.
B. Kotelly
No textbook information available

2.729[J] D-Lab: Design for Scale
______

Undergrad (Fall)
(Same subject asEC.729[J])
Prereq: Permission of instructor
Units: 3-2-7
Lecture: TR11.30-1 (N51-350) Recitation: R1-2.30 (N51-350)
______
Focuses on product development of technologies for people in less industrialized markets. Students work in interdisciplinary teams to develop previously established prototypes or technologies towards manufacturing-ready product designs. Topics are presented within the context of the developing world and include technology feasibility and scalability assessment; value chain analysis; product specification; design for affordability, manufacturability, usability, and desirability; and product testing and manufacturing at various scales. Lessons are experiential and case study-based; taught by instructors with field experience and by industry experts from product development consulting firms and the consumer electronics industry.
M. McCambridge, M. Yang, H. Quintus-Bosz
No textbook information available

2.737 Mechatronics
______

Graduate (Fall)
Prereq: 6.071 or 6.002; 2.14, 6.302, or 16.30
Units: 3-5-4
Lecture: MW2.30-4 (1-246) Lab: T2-5 (1-004) or R2-5 (1-004)
______
Introduction to designing mechatronic systems, which require integration of the mechanical and electrical engineering disciplines within a unified framework. Significant laboratory-based design experiences form subject's core. Final project. Topics include: low-level interfacing of software with hardware; use of high-level graphical programming tools to implement real-time computation tasks; digital logic; analog interfacing and power amplifiers; measurement and sensing; electromagnetic and optical transducers; control of mechatronic systems. Limited to 20.
D. L. Trumper, K. Youcef-Toumi
No required or recommended textbooks

2.739[J] Product Design and Development
______

Graduate (Spring)
(Same subject as15.783[J])
Prereq: 2.009, 15.761, 15.778, 15.810, or permission of instructor
Units: 3-3-6
URL: http://web.mit.edu/15.783j/www/
______
Covers modern tools and methods for product design and development. Includes a cornerstone project in which teams conceive, design and prototype a physical product and/or service. Covers design thinking, product planning, identifying customer needs, concept generation, product architecture, industrial design, concept design, green design methods, and product management. Sloan students register via Sloan course bidding. Engineering students accepted via lottery based on WebSIS pre-registration.
S. Eppinger, M. C. Yang

2.74 Bio-inspired Robotics
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with2.740)
Prereq: 2.004 or permission of instructor
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Interdisciplinary approach to bio-inspired design, with emphasis on principle extraction applicable to various robotics research fields, such as robotics, prosthetics, and human assistive technologies. Focuses on three main components: biomechanics, numerical techniques that allow multi-body dynamics simulation with environmental interaction and optimization, and basic robotics techniques and implementation skills. Students integrate the components into a final robotic system project of their choosing through which they must demonstrate their understanding of dynamics and control and test hypothesized design principles. Students taking graduate version complete additional assignments. Enrollment may be limited due to laboratory capacity.
S. Kim

2.740 Bio-inspired Robotics
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with2.74)
Prereq: 2.004 or permission of instructor
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Interdisciplinary approach to bio-inspired design, with emphasis on principle extraction applicable to various robotics research fields, such as robotics, prosthetics, and human assistive technologies. Focuses on three main components: biomechanics, numerical techniques that allow multi-body dynamics simulation with environmental interaction and optimization, and basic robotics techniques and implementation skills. Students integrate the components into a final robotic system project of their choosing through which they must demonstrate their understanding of dynamics and control and test hypothesized design principles. Students taking graduate version complete additional assignments. Enrollment may be limited due to lab capacity.
S. Kim

2.744 Product Design
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 2.009
Units: 3-0-9
URL: http://me.mit.edu/2.744/
______
Project-centered subject addressing transformation of ideas into successful products which are properly matched to the user and the market. Students are asked to take a more complete view of a new product and to gain experience with designs judged on their aesthetics, ease of use, and sensitivities to the realities of the marketplace. Lectures on modern design process, industrial design, visual communication, form-giving, mass production, marketing, and environmentally conscious design.
D. R. Wallace

2.75[J] Medical Device Design
______

Graduate (Fall)
(Same subject as6.525[J],HST.552[J])
(Subject meets with2.750[J],6.025[J])
Prereq: 2.72, 6.101, 6.111, 6.115, 22.071, or permission of instructor
Units: 3-0-9
2.75: URL: https://web.mit.edu/2.75/
2.750: URL: https://web.mit.edu/2.75/
2.75: Lecture: MW1-2.30 (3-270)
2.750: Lecture: MW1-2.30 (3-270)
______
2.75: No required or recommended textbooks
2.750: No required or recommended textbooks

2.750[J] Medical Device Design
______

Undergrad (Fall)
(Same subject as6.025[J])
(Subject meets with2.75[J],6.525[J],HST.552[J])
Prereq: 2.72, 6.101, 6.111, 6.115, 22.071, or permission of instructor
Units: 3-0-9
2.75: URL: https://web.mit.edu/2.75/
2.750: URL: https://web.mit.edu/2.75/
2.75: Lecture: MW1-2.30 (3-270)
2.750: Lecture: MW1-2.30 (3-270)
______
Application of mechanical and electrical engineering fundamentals to the design of medical devices that address clinical needs. Throughout the term, students work in small teams on a major project to translate a clinical challenge into a proof-of-concept prototype device. Students conduct user analysis, develop design specifications, and follow a structured process to cultivate creative designs and apply analytical techniques to optimize them. They deepen their understanding of art and intellectual property by researching prior representations. Develops practical skills in prototyping and testing as well as project management. Includes lectures, problem sets and exams that focus on design fundamentals. Instruction and practice in written and oral communication provided. Students taking graduate version complete additional assignments. Enrollment limited.
A. H. Slocum, G. Hom
2.75: No required or recommended textbooks
2.750: No required or recommended textbooks

2.752 Development of Mechanical Products
______

Undergrad (Spring)
(Subject meets with2.753)
Prereq: 2.750, 2.009, or permission of instructor
Units: 3-0-9
______

2.753 Development of Mechanical Products
______

Graduate (Spring)
(Subject meets with2.752)
Prereq: 2.750, 2.009, or permission of instructor
Units: 3-0-9
______
Focuses on evolving a product from proof-of-concept to beta prototype: Includes team building, project planning, budgeting, resource planning; models for scaling, tolerancing and reliability, patents, business planning. Students/teams start with a proof-of-concept product they bring to class or select from projects provided by instructor. In lieu of taking 12 units of 2.THU, Course 2 majors taking 2.752 may write a bachelor's thesis that documents their contributions to the product developed in the team project. Students taking the graduate version complete additional assignments. Enrollment limited.
A. Slocum

2.76 Global Engineering
______

Graduate (Fall)
(Subject meets with2.760)
Prereq: 2.008 or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (3-333)
______
Combines rigorous engineering theory and user-centered product design to create technologies for developing and emerging markets. Covers machine design theory to parametrically analyze technologies; bottom-up/top-down design processes; engagement of stakeholders in the design process; socioeconomic factors that affect adoption of products; and developing/emerging market dynamics and their effect on business and technology. Includes guest lectures from subject matter experts in relevant fields and case studies on successful and failed technologies. Student teams apply course material to term-long projects to create new technologies, developed in collaboration with industrial partners and other stakeholders in developing/emerging markets. Students taking graduate version complete additional assignments.
A. Winter
Textbooks (Fall 2016)

2.760 Global Engineering
______

Undergrad (Fall)
(Subject meets with2.76)
Prereq: 2.008 or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (3-333)
______
Combines rigorous engineering theory and user-centered product design to create technologies for developing and emerging markets. Covers machine design theory to parametrically analyze technologies; bottom-up/top-down design processes; engagement of stakeholders in the design process; socioeconomic factors that affect adoption of products; and developing/emerging market dynamics and their effect on business and technology. Includes guest lectures from subject matter experts in relevant fields and case studies on successful and failed technologies. Student teams apply course material to term-long projects to create new technologies, developed in collaboration with industrial partners and other stakeholders in developing/emerging markets. Students taking graduate version complete additional assignments.
A. Winter
No textbook information available

Bioengineering

2.772[J] Thermodynamics of Biomolecular Systems
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
(Same subject as20.110[J])
Prereq: Calculus II (GIR), Chemistry (GIR), Physics I (GIR)
Units: 5-0-7
Lecture: MWF10 (4-270) Recitation: TR10 (26-168) or TR1 (66-154) or TR4 (56-169) +final
______
Equilibrium properties of macroscopic and microscopic systems. Basic thermodynamics: state of a system, state variables. Work, heat, first law of thermodynamics, thermochemistry. Second and third law of thermodynamics: entropy and its statistical basis, Gibbs function. Chemical equilibrium of reactions in gas and solution phase. Macromolecular structure and interactions in solution. Driving forces for molecular self-assembly. Binding cooperativity, solvation, titration of macromolecules.
Fall:M. Birnbaum C. Voigt
Spring:E. Alm, C. Voigt
No textbook information available

2.78[J] Principles and Practice of Assistive Technology
(New)
______

Undergrad (Fall)
(Same subject as6.811[J],HST.420[J])
Prereq: Permission of instructor
Units: 2-4-6
Lecture: M2 (32-144) Lab: W2-5 (32-044)
______
Students work closely with people with disabilities to develop assistive and adaptive technologies that help them live more independently. Covers design methods and problem-solving strategies; human factors; human-machine interfaces; community perspectives; social and ethical aspects; and assistive technology for motor, cognitive, perceptual, and age-related impairments. Prior knowledge of one or more of the following areas useful: software; electronics; human-computer interaction; cognitive science; mechanical engineering; control; or MIT hobby shop, MIT PSC, or other relevant independent project experience.
R. C. Miller, J. E. Greenberg, J. J. Leonard
Textbooks (Fall 2016)

2.782[J] Design of Medical Devices and Implants
______

Graduate (Spring)
(Same subject as3.961[J],20.451[J],HST.524[J])
Prereq: Chemistry (GIR), Biology (GIR), Physics I (GIR); or permission of instructor
Units: 3-0-9
______
Solution of clinical problems by use of implants and other medical devices. Systematic use of cell-matrix control volumes. The role of stress analysis in the design process. Anatomic fit: shape and size of implants. Selection of biomaterials. Instrumentation for surgical implantation procedures. Preclinical testing for safety and efficacy: risk/benefit ratio assessment. Evaluation of clinical performance: design of clinical trials. Project materials drawn from orthopedic devices, soft tissue implants, artificial organs, and dental implants.
I. V. Yannas, M. Spector

2.785[J] Cell-Matrix Mechanics
______

Graduate (Fall)
(Same subject as3.97[J],HST.523[J])
Prereq: 2.001, or 2.01 and 2.02A; Chemistry (GIR), Biology (GIR); or permission of instructor
Units: 3-0-9
Lecture: TR11-12.30 (1-371)
______
Mechanical forces play a decisive role during development of tissues and organs, during remodeling following injury as well as in normal function. A stress field influences cell function primarily through deformation of the extracellular matrix to which cells are attached. Deformed cells express different biosynthetic activity relative to undeformed cells. The unit cell process paradigm combined with topics in connective tissue mechanics form the basis for discussions of several topics from cell biology, physiology, and medicine.
I. V. Yannas, M. Spector
No required or recommended textbooks

2.79[J] Biomaterials: Tissue Interactions
______

Graduate (Fall)
(Same subject as3.96[J],HST.522[J])
Prereq: Chemistry (GIR), Biology (GIR), Physics I (GIR); or permission of instructor
Units: 3-0-9
Lecture: TR2.30-4 (3-370)
______
Principles of materials science and cell biology underlying the development and implementation of biomaterials for the fabrication of medical devices/implants, including artificial organs and matrices for tissue engineering and regenerative medicine. Employs a conceptual model, the "unit cell process for analysis of the mechanisms underlying wound healing and tissue remodeling following implantation of biomaterials/devices in various organs, including matrix synthesis, degradation, and contraction. Methodology of tissue and organ regeneration. Discusses methods for biomaterials surface characterization and analysis of protein adsorption on biomaterials. Design of implants and prostheses based on control of biomaterials-tissue interactions. Comparative analysis of intact, biodegradable, and bioreplaceable implants by reference to case studies. Criteria for restoration of physiological function for tissues and organs.
I. V. Yannas, M. Spector
Textbooks (Fall 2016)

2.791[J] Cellular Neurophysiology
______

Undergrad (Fall)
(Same subject as6.021[J],20.370[J])
(Subject meets with2.794[J],6.521[J],20.470[J],HST.541[J])
Prereq: Physics II (GIR); 18.03; 2.005, 6.002, 6.003, 6.071, 10.301, 20.110, or permission of instructor
Units: 5-2-5
Lecture: MWF10 (32-144) Lab: TBA Recitation: T12 (34-303) or T4 (34-302) +final
______
Integrated overview of the biophysics of cells from prokaryotes to neurons, with a focus on mass transport and electrical signal generation across cell membrane. First half of course focuses on mass transport through membranes: diffusion, osmosis, chemically mediated, and active transport. Second half focuses on electrical properties of cells: ion transport to action potentials in electrically excitable cells. Synaptic transmission. Electrical properties interpreted via kinetic and molecular properties of single voltage-gated ion channels. Laboratory and computer exercises illustrate the concepts. Students taking graduate version complete different assignments. Preference to juniors and seniors.
J. Han, T. Heldt, J. Voldman
Textbooks (Fall 2016)

2.792[J] Quantitative Systems Physiology
______

Undergrad (Spring)
(Same subject as6.022[J],HST.542[J])
(Subject meets with2.796[J],6.522[J])
Prereq: Physics II (GIR), 18.03, or permission of instructor
Units: 4-2-6
URL: http://web.mit.edu/6.022j/www/
______
Application of the principles of energy and mass flow to major human organ systems. Mechanisms of regulation and homeostasis. Anatomical, physiological and pathophysiological features of the cardiovascular, respiratory and renal systems. Systems, features and devices that are most illuminated by the methods of physical sciences. Laboratory work includes some animal studies. Students taking graduate version complete additional assignments.
T. Heldt, R. G. Mark, C. M. Stultz

2.793[J] Fields, Forces and Flows in Biological Systems
______

Undergrad (Spring)
(Same subject as6.023[J],20.330[J])
Prereq: Physics II (GIR); 2.005, 6.021, or permission of instructor,Coreq: 20.309
Units: 4-0-8
______
Introduction to electric fields, fluid flows, transport phenomena and their application to biological systems. Flux and continuity laws, Maxwell's equations, electro-quasistatics, electro-chemical-mechanical driving forces, conservation of mass and momentum, Navier-Stokes flows, and electrokinetics. Applications include biomolecular transport in tissues, electrophoresis, and microfluidics.
J. Han, S. Manalis

2.794[J] Cellular Neurophysiology
______

Graduate (Fall)
(Same subject as6.521[J],20.470[J],HST.541[J])
(Subject meets with2.791[J],6.021[J],20.370[J])
Prereq: Physics II (GIR); 18.03; 2.005, 6.002, 6.003, 6.071, 10.301, 20.110, or permission of instructor
Units: 5-2-5
Lecture: MWF10 (32-144) Lab: TBA Recitation: T12 (34-303) or T4 (34-302) +final
______
Meets with undergraduate subject 6.021J. Requires the completion of more advanced home problems and/or an additional project.
J. Han, T. Heldt
Textbooks (Fall 2016)

2.795[J] Fields, Forces, and Flows in Biological Systems
______

Graduate (Fall)
(Same subject as6.561[J],10.539[J],20.430[J])
Prereq: 6.013, 2.005, 10.302, or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (32-124)
______
Molecular diffusion, diffusion-reaction, conduction, convection in biological systems; fields in heterogeneous media; electrical double layers; Maxwell stress tensor, electrical forces in physiological systems. Fluid and solid continua: equations of motion useful for porous, hydrated biological tissues. Case studies of membrane transport, electrode interfaces, electrical, mechanical, and chemical transduction in tissues, convective-diffusion/reaction, electrophoretic, electroosmotic flows in tissues/MEMs, and ECG. Electromechanical and physicochemical interactions in cells and biomaterials; musculoskeletal, cardiovascular, and other biological and clinical examples.
M. Bathe, A. J. Grodzinsky
Textbooks (Fall 2016)

2.796[J] Quantitative Physiology: Organ Transport Systems
______

Graduate (Spring)
(Same subject as6.522[J])
(Subject meets with2.792[J],6.022[J],HST.542[J])
Prereq: 2.006 or 6.013; 6.021
Units: 4-2-6
______
Application of the principles of energy and mass flow to major human organ systems. Mechanisms of regulation and homeostasis. Anatomical, physiological and pathophysiological features of the cardiovascular, respiratory and renal systems. Systems, features and devices that are most illuminated by the methods of physical sciences. Laboratory work includes some animal studies. Students taking graduate version complete additional assignments.
T. Heldt, R. G. Mark, C. M. Stultz

2.797[J] Molecular, Cellular, and Tissue Biomechanics
______

Undergrad (Spring)
(Same subject as3.053[J],6.024[J],20.310[J])
Prereq: 2.370 or 2.772J; 18.03 or 3.016; Biology (GIR)
Units: 4-0-8
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, A. J. Grodzinsky, K. Van Vliet

2.798[J] Molecular, Cellular, and Tissue Biomechanics
______

Graduate (Fall)
(Same subject as3.971[J],6.524[J],10.537[J],20.410[J])
Prereq: Biology (GIR); 2.002, 2.006, 6.013, 10.301, or 10.302
Units: 3-0-9
Lecture: TR10.30-12 (2-143)
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, K. J. Van Vliet
No textbook information available

2.799 The Cell as a Machine
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 5.07, 18.03, or 7.05
Units: 3-3-6
______
Examines a variety of essential cellular functions from the perspective of the cell as a machine. Includes phenomena such as nuclear organization, protein synthesis, cell and membrane mechanics, cell migration, cell cycle control, cell transformation. Lectures are provided by video twice per week; live 3-hour recitation one evening per week. Course is taken simultaneously by students at multiple universities; homework and take-home exams common to all students. Preference to students in Courses 2 and 20.
R. Kamm, M. Sheetz, H. Yu


left arrow|2.000-2.199|2.20-2.7999|2.80-2.999 plus Thesis, UROP, UPOP|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 2: Mechanical Engineering
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Course 2: Mechanical Engineering
Fall 2016


Manufacturing

2.810 Manufacturing Processes and Systems
______

Graduate (Fall)
Prereq: 2.001, 2.006, 2.008
Units: 3-3-6
Lecture: MW2.30-4 (37-212) Lab: M9-12 (35-125) or W9-12 (35-125) or R9-12 (35-125) or F9-12 (35-125)
______
Introduction to manufacturing processes and manufacturing systems including assembly, machining, injection molding, casting, thermoforming, and more. Emphasis on the physics and randomness and how they influence quality, rate, cost, and flexibility. Attention to the relationship between the process and the system, and the process and part design. Project (in small groups) requires fabrication (and some design) of a product using several different processes (as listed above). Enrollment may be limited due to laboratory constraints.
T. G. Gutowski
Textbooks (Fall 2016)

2.813 Energy, Materials, and Manufacturing
______

Undergrad (Spring)
(Subject meets with2.83)
Prereq: 2.008 or permission of instructor
Units: 3-0-9
______
Introduction to the major dilemma that faces manufacturing and society for the 21st century: how to support economic development while protecting the environment. Subject addresses industrial ecology, materials flows, life-cycle analysis, thermodynamic analysis and exergy accounting, manufacturing process performance, product design analysis, design for the environment, recycling and ecological economics. Combines lectures and group discussions of journal articles and selected literature, often with opposing views. Graduate students complete term-long project with report required for graduate credit.
T. G. Gutowski

2.821[J] Selection and Processing of Structural Materials
______

Graduate (Fall, Spring, Summer) Can be repeated for credit; partial term
(Same subject as3.371[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: MWF9 (4-145) Recitation: TR9 (4-145)
______
Discusses selection design and processing for structural materials, including casting, forging, rolling, drawing, extrusion, powder consolidation, welding, brazing, soldering, wear, corrosion, non-destructive testing and fracture. Emphasizes the underlying science of a given process rather than a detailed description of the technique or equipment. Presented in modules; repeatable for credit one time with permission of instructor, provided three different modules are selected the second term.
T. Eagar
No required or recommended textbooks
______
Summer 2016 Description for Selection and Processing of Structural Materials
(Same subject as 2.821J) (Subject meets with 3.S171)
Prereq:Permission of instructor
Units: 3-0-9
Can be repeated for credit

Discusses selection design and processing for structural materials, including casting, forging, rolling, drawing, extrusion, powder consolidation, welding, brazing, soldering, wear, corrosion, non-destructive testing and fracture. Emphasizes the underlying science of a given process rather than a detailed description of the technique or equipment. Presented in modules; repeatable for credit one time with permission of instructor, provided three different modules are selected the second term.

T. Eager
Section: MTWThF 8:00 AM-10:00 AM Room 4-145 From 06-JUN-16 Thru 22-JUL-16

2.83 Energy, Materials and Manufacturing
______

Graduate (Spring)
(Subject meets with2.813)
Prereq: 2.008 or permission of instructor
Units: 3-0-9
______
Introduction to the major dilemma that faces manufacturing and society for the 21st century: how to support economic development while protecting the environment. Subject addresses industrial ecology, materials flows, life-cycle analysis, thermodynamic analysis and exergy accounting, manufacturing process performance, product design analysis, design for the environment, recycling and ecological economics. Combines lectures and group discussions of journal articles and selected literature, often with opposing views. Graduate students complete term-long project with report required for graduate credit.
T. G. Gutowski

2.830[J] Control of Manufacturing Processes
______

Graduate (Spring)
(Same subject as6.780[J])
Prereq: 2.008, 6.041B, 6.152, or 15.064
Units: 3-0-9
______
Statistical modeling and control in manufacturing processes. Use of experimental design and response surface modeling to understand manufacturing process physics. Defect and parametric yield modeling and optimization. Forms of process control, including statistical process control, run by run and adaptive control, and real-time feedback control. Application contexts include semiconductor manufacturing, conventional metal and polymer processing, and emerging micro-nano manufacturing processes.
D. E. Hardt, D. S. Boning

2.851[J] System Optimization and Analysis for Operations
______

Graduate (Summer)
(Same subject as15.066[J])
Prereq: Calculus II (GIR)
Units: 4-0-8
______
Introduction to mathematical modeling, optimization, and simulation, as applied to manufacturing. Specific methods include linear programming, network flow problems, integer and nonlinear programming, discrete-event simulation, heuristics and computer applications for manufacturing processes and systems. Restricted to Leaders for Global Operations students.
V. Farias
No textbook information available

2.852 Manufacturing Systems Analysis
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 6.041B or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/manuf-sys/www/syllabus.html
______
Models of manufacturing systems, including transfer lines and flexible manufacturing systems. Calculation of performance measures, including throughput, in-process inventory, and meeting production commitments. Real-time control of scheduling. Effects of machine failure, set-ups, and other disruptions on system performance.
S. B. Gershwin

2.853 Introduction to Manufacturing Systems
______

Undergrad (Fall)
(Subject meets with2.854)
Prereq: 2.008
Units: 3-0-9
Lecture: TR9.30-11 (3-333)
______
No textbook information available

2.854 Introduction to Manufacturing Systems
______

Graduate (Fall)
(Subject meets with2.853)
Prereq: Undergraduate mathematics
Units: 3-0-9
Lecture: TR9.30-11 (3-333)
______
Provides ways to analyze manufacturing systems in terms of material flow and storage, information flow, capacities, and times and durations of events. Fundamental topics include probability, inventory and queuing models, forecasting, optimization, process analysis, and linear and dynamic systems. Factory planning and scheduling topics include flow planning, bottleneck characterization, buffer and batch-size tactics, seasonal planning, and dynamic behavior of production systems. Graduate students are required to complete additional assignments.
S. B. Gershwin
No textbook information available

2.888 Professional Seminar in Global Manufacturing Innovation and Entrepreneurship
______

Graduate (Spring)
Prereq: None
Units: 2-0-1
______
Covers a broad range of topics in modern manufacturing, from models and structures for 21st-century operations, to case studies in leadership from the shop floor to the executive office. Also includes global perspectives from Asia, Europe and North America, with guest speakers from all three regions. Explores opportunities for new ventures in manufacturing. Intended primarily for Master of Engineering in Manufacturing students.
D. E. Hardt, S. B. Gershwin

2.890[J] Global Operations Leadership Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as10.792[J],15.792[J],16.985[J])
Prereq: None
Units arranged [P/D/F]
Lecture: M EVE (4-6 PM) (E62-262)
______
Integrative forum in which worldwide leaders in business, finance, government, sports, and education share their experiences and insights with students aspiring to run global operations. Students play a large role in managing the seminar. Preference to LGO students.
T. Roemer
No textbook information available

Engineering Management

2.900 Ethics for Engineers
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.082,2.900,6.904,10.01,22.014)
Prereq: None
Units: 2-0-4
Lecture: M3-5 (66-144, 36-153) or T3-5 (37-212) or T EVE (7.30-9.30 PM) (66-144) or W3-5 (36-153)
______
Integrates classical readings that provide an overview of ethics with a survey of case studies that focus on ethical problems arising in the practice of engineering. Readings taken from a variety of sources, such as Aristotle, Machiavelli, Bacon, Hobbes, Locke, the Founding Fathers, and the Bible. Case studies include written analyses and films that address engineering disasters, biotechnology, court cases, ethical codes, and the ultimate scope and aims of engineering.
D. Doneson, B. L. Trout
No textbook information available

2.912[J] Venture Engineering
(New)
______

Undergrad (Spring)
(Same subject as15.373[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Develops the capability to move from testing ideas to assembling a venture as a system comprised of technological, human, social, regulatory, managerial, and financial processes and flows that affect costs, revenues, and value. Begins with a focus on leadership, addressing key issues involved in recruiting and building a founder team and its early employees. Fosters understanding of financial resource needs for the new enterprise and methods for raising funds. Students engage in a venture planning activity in which they must demonstrate their understanding of the concepts covered in class.
F. Murray

2.916[J] Funding Strategies for Startups
______

Graduate (Spring); second half of term
(Same subject as10.407[J])
Prereq: None
Units: 2-0-4
______
Introduction to the substance and process of funding technology startups. Topics include a comparative analysis of various sources of capital; templates to identify the optimal investor; legal frameworks, US and offshore, of the investment process and its related jargon; an introduction to understanding venture capital as a business; and market practice and standards for term sheet negotiation. Emphasizes strategy as well as tactics necessary to negotiate and build effective, long-term relationships with investors, particularly venture capital firms (VCs).
S. Loessberg, D. P. Hart

2.96 Management in Engineering
______

Undergrad (Fall)
Engineering School-Wide Elective Subject.
(Offered under:2.96,6.930,10.806,16.653)
Prereq: None
Units: 3-1-8
Lecture: MW11-12.30 (35-225) Lab: M4 (35-308) or T10 (1-273) or R4 (1-371) or F1 (1-132) or F2 (1-132)
______
No textbook information available

2.961 Management in Engineering
______

Graduate (Fall)
Prereq: None
Units: 3-1-8
Lecture: MW11-12.30 (35-225) Lab: M4 (35-310)
______
Introduction and overview of engineering management. Financial principles, management of innovation, technical strategy and best management practices. Case study method of instruction emphasizes participation in class discussion. Focus is on the development of individual skills and management tools.
J.-H. Chun, H. S. Marcus
No textbook information available

2.965[J] Global Supply Chain Management
______

Graduate (Spring)
(Same subject as1.265[J],15.765[J],SCM.265[J])
Prereq: 1.260, 1.261, 15.761, 15.778, or permission of instructor
Units: 2-0-4
______
Focuses on the planning, processes, and activities of supply chain management for companies involved in international commerce. Students examine the end-to-end processes and operational challenges in managing global supply chains, such as the basics of global trade, international transportation, duty, taxes, trade finance and hedging, currency issues, outsourcing, cultural differences, risks and security, and green supply chains issues. Highly interactive format features student-led discussions, staged debates, and a mock trial. Includes assignments on case studies and sourcing analysis, as well as projects and a final exam.
B. Arntzen

Advanced Topics and Special Subjects

2.98 Sports Technology: Engineering & Innovation
(New)
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: F3-5 (1-390)
______
Examines the future of sports technology across technical disciplines including mechanical design, biomechanics, quantified self, sports analytics, and business strategies. Leaders in the field will be brought in to discuss various industries, career pathways and opportunities for innovation in the field. Class projects will explore and potentially kickoff larger research and/or entrepreneurial initiatives. Open to undergraduate and graduate students.
A. Hosoi, C. Chase
No textbook information available

2.981 New England Coastal Ecology
______

Undergrad (IAP)
Prereq: None
Units: 2-0-1 [P/D/F]
______
Provides exposure to marine communities found along the coast of New England and how they fit into global patterns. Focuses on the ecology of salt marshes and rocky shores, and the biology of plants and animals that live in these complex habitats. Prepares students to recognize common inhabitants of these two communities and develops understanding of the major environmental factors affecting them, the types of ecological services they provide, and likely impacts of current and future climate change. Includes visits to field and research centers. Limited to 20.
Consult C. Bastidas

2.990 Practical Work Experience
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units: 0-1-0 [P/D/F]
TBA.
______
For Mechanical Engineering undergraduates participating in curriculum-related off-campus work experiences in mechanical engineering. Before enrolling, students must have an employment offer from a company or organization and must find a Mech E supervisor. Upon completion of the work the student must submit a detailed design notebook, approved by the MIT supervisor. Subject to departmental approval. Consult Department Undergraduate Office for details on procedures and restrictions.
A. Slocum
No textbook information available

2.993, 2.994 Independent Study
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
2.993: TBA.
2.994: TBA.
______
Designed for undergraduates wanting to continue substantial projects of own choice, under faculty supervision, in mechanical engineering. Work may be of experimental, theoretical, or design nature. Projects may be arranged individually in most fields of department interest, i.e., in mechanics, design and manufacturing, controls and robotics, thermal science and energy engineering, bioengineering, ocean engineering and nanotechnology. 2.993 is letter-graded; 2.994 is P/D/F.
Consult A. E. Hosoi
2.993: No textbook information available
2.994: No textbook information available

2.995 Advanced Topics in Mechanical Engineering
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
URL: http://www-mtl.mit.edu/Courses/6.095
TBA.
______
Assigned reading and problems or research in distinct areas, either theoretical or experimental, or design. Arranged on individual basis with instructor in the following areas: mechanics and materials, thermal and fluid sciences, systems and design, biomedical engineering, and ocean engineering. Can be repeated for credit only for completely different subject matter.
Consult R. Abeyaratne
No textbook information available

2.996-2.998 Advanced Topics in Mechanical Engineering
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
2.996: TBA.
2.997: TBA.
2.998: Lecture: TR11.30-1 (N51-350) Recitation: R1-2.30 (N51-350)
______
Assigned reading and problems or research in distinct areas, either theoretical or experimental, or design. Arranged on individual basis with instructor in the following areas: mechanics and materials, thermal and fluid sciences, systems and design, biomedical engineering, and ocean engineering. Can be repeated for credit only for completely different subject matter.
Consult R. Abeyaratne
2.996: No textbook information available
2.997: No textbook information available
2.998: No textbook information available

2.S790-2.S792 Graduate Special Subject in Bioengineering
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Advanced lecture, seminar or laboratory course consisting of material in the broadly-defined field of bioengineering not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Consult R. Kamm

2.S97 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

2.S971 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

2.S972 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (Fall) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
Lecture: F2-4 (3-370)
______
No textbook information available

2.S973 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (Fall) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
Lecture: T1-2.30 (E40-160)
______
No textbook information available

2.S974 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
______
Lecture, seminar or laboratory course consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter. 2.S972-2.S974 are graded P/D/F.
Consult A. E. Hosoi

2.S980 Graduate Special Subject in Mechanical Engineering
______

Graduate (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______

2.S981 Graduate Special Subject in Mechanical Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
Subject Cancelled Subject Cancelled
______

2.S982 Graduate Special Subject in Mechanical Engineering
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
Subject Cancelled Subject Cancelled
______

2.S992 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
Subject Cancelled Subject Cancelled
______

2.S993 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (Fall) Can be repeated for credit
Prereq: None
Units arranged
Lecture: TR11-12.30 (1-132) Lab: R2.30-4.30 (1-115)
______
No required or recommended textbooks

2.S994 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
Subject Cancelled Subject Cancelled
______

2.S995 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
Subject Cancelled Subject Cancelled
______

2.S996 Graduate Special Subject in Mechanical Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
Subject Cancelled Subject Cancelled
______

2.S997 Graduate Special Subject in Mechanical Engineering
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: MW11-12.30 (1-273) Recitation: R3 (1-134)
______
No textbook information available

2.S998 Graduate Special Subject in Mechanical Engineering
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: TR1-2.30 (1-375)
______
No required or recommended textbooks

2.S999 Graduate Special Subject in Mechanical Engineering
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: TR2.30-5 (NE45-202)
______
Advanced lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter. 2.S980 and 2.S996 are graded P/D/F.
Consult R. Abeyaratne
No textbook information available

Thesis, Research and Practice

2.978 Instruction in Teaching Engineering
______

Graduate (Fall)
(Subject meets with1.95[J],5.95[J],7.59[J],8.395[J],18.094[J])
Prereq: Permission of instructor
Units arranged [P/D/F]
Lecture: R9-11 (4-149)
______
Participatory seminar focuses on the knowledge and skills necessary for teaching engineering in higher education. Topics include research on learning; course development; promoting active learning, problemsolving, and critical thinking in students; communicating with a diverse student body; using educational technology to further learning; lecturing; creating effective tests and assignments; and assessment and evaluation. Field-work teaching various subjects in the Mechanical Engineering department will complement classroom discussions.
J. Rankin
No textbook information available

2.979 Undergraduate Teaching
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
For students participating in departmentally approved undergraduate teaching programs. Students assist faculty in the design and execution of the curriculum and actively participate in the instruction and monitoring of the class participants. Students prepare subject materials, lead discussion groups, and review progress. Credit is arranged on a subject-by-subject basis and is reviewed by the department.
A. E. Hosoi
No textbook information available

2.999 Engineer's Degree Thesis Proposal Preparation
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
For students who must do additional work to convert an SM thesis to an ME thesis, or for students who write an ME thesis after having received an SM degree.
R. Abeyaratne, M. S. Triantafyllou
No textbook information available

2.EPE UPOP Engineering Practice Experience
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.EPE,2.EPE,3.EPE,6.EPE,10.EPE,16.EPE,22.EPE)
Prereq: 2.EPW or permission of instructor
Units: 0-0-1 [P/D/F]
TBA.
______
Provides sophomores with guided practice in finding opportunities and excelling in the world of practice. Building on the skills and relationships acquired in the Engineering Practice Workshop, students receive coaching to articulate goals, invoke the UPOP network of mentors and employers, identify and pursue opportunities and negotiate terms of their summer assignment. Students complete a 10-12 week internship, which includes filing three progress reports, conducting one informational interview, and possibly hosting a site visit by MIT staff. Returning to campus as juniors, UPOP students take part in reflective exercises that aid assimilation of learning objectives and reinforce the cognitive link between all aspects of the UPOP experience and disciplinary fields of study. Sequence begins in the spring of sophomore year and ends in the fall of junior year.
Staff
No textbook information available

2.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No textbook information available

2.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of advisor
Units arranged
TBA.
______
Program of research leading to the writing of an SM, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member.
Consult R. Abeyaratne
Textbooks arranged individually

2.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Individual self-motivated study, research, or design project under faculty supervision. Departmental program requirement: minimum of 6 units. Instruction and practice in written communication provided.
Consult A. E. Hosoi
Textbooks arranged individually

2.UR Undergraduate Research in Mechanical Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually

2.URG Undergraduate Research in Mechanical Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Individual study, research, or laboratory investigations under faculty supervision, including individual participation in an ongoing research project. See projects listing in Undergraduate Office, 1-110, for guidance.
Consult N. Fang, K. Kamrin
Textbooks arranged individually


left arrow|2.000-2.199|2.20-2.7999|2.80-2.999 plus Thesis, UROP, UPOP|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 3: Materials Science and Engineering
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Course 3: Materials Science and Engineering
Fall 2016


3.003 Principles of Engineering Practice
______

Undergrad (Spring)
(Subject meets with3.004)
Prereq: Physics I (GIR), Calculus I (GIR)
Units: 1-2-6
URL: http://web.mit.edu/3.003/www/
______
Introduces students to the interdisciplinary nature of 21st-century engineering projects with three threads of learning: a technical toolkit, a social science toolkit, and a methodology for problem-based learning. Students encounter the social, political, economic, and technological challenges of engineering practice by participating in actual engineering projects involving public transportation and information infrastructure with faculty and industry. Student teams create prototypes and mixed media reports with exercises in project planning, analysis, design, optimization, demonstration, reporting and team building. Preference to freshmen.
L. Kimerling

3.004 Principles of Engineering Practice
______

Undergrad (Spring)
(Subject meets with3.003)
Prereq: Physics I (GIR),Calculus I (GIR)
Units: 3-3-6
______
Introduces students to the interdisciplinary nature of 21st-century engineering projects with three threads of learning: a technical toolkit, a social science toolkit, and a methodology for problem-based learning. Students encounter the social, political, economic and technological challenges of engineering practice via case studies and participation in engineering projects. Includes a six-stage term project in which student teams develop solutions through exercises in project planning, analysis, design, optimization, demonstration, reporting, and team building.
L. Kimerling

3.005 Passion Projects: Living in a Material World
______

Undergrad (Spring)
Prereq: None
Units: 1-2-6
______
Project-based seminar in which students formulate and answer questions about a material or object that interests and inspires them. Uses cutting-edge equipment to characterize the materials' structure in order to understand its role and functionality. Analyzes the lifecycle of the material to better understand the full use case. Culminates in the creation of a website, video, and final presentation in which students share the results of their research. Preference to freshmen; limited to 15.
K. Van Vliet

3.012 Fundamentals of Materials Science and Engineering
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: None.Coreq: 18.03, 18.034, or 3.016
Units: 5-0-10
Lecture: MWF1-3 (4-370) Recitation: TR1 (4-265) or TR2 (4-265) +final
______
Describes the fundamentals of structure and energetics that underpin materials science. Presents thermodynamic concepts and the laws governing equilibrium properties, and the connections between thermodynamic concepts and materials phenomena, such as phase transformations, multiphase equilibria, and chemical reactions. Introduces computerized thermodynamics. Structure of noncrystalline, crystalline, and liquid-crystalline states. Symmetry and tensor properties of materials. Point, line, and surface imperfections in materials. Diffraction and structure determination.
S. Gradečak, R. Jaramillo
Textbooks (Fall 2016)

3.014 Materials Laboratory
______

Undergrad (Fall) Institute Lab
Prereq: None
Units: 1-4-7
Lab: MWF1-5 (8-107) Recitation: TR1 (4-265) or TR2 (4-265) +final
______
Experimental exploration of the connections between structure, properties, processing, and performance of materials. Hands-on experience with materials characterization techniques and instrumentation. Covers methodology of technical communication (written and oral) with a view to integrate experimental design, execution, and analysis. Concurrent enrollment in 3.012 and 3.014 strongly recommended.
L. Kimerling, D. Sadoway
No required or recommended textbooks

3.016 Computational Methods for Materials Scientists and Engineers
______

Undergrad (Fall)
Prereq: Calculus II (GIR)
Units: 3-1-8
URL: http://pruffle.mit.edu/3.016
Thurs recitation meets in 37-. Lecture: MWF4 (W31-301) Lab: R EVE (7.30 PM) (W31-301) Recitation: TBA or R2 (W31-301)
______
Computational and analytical techniques necessary for materials science and engineering topics, such as material structure, symmetry, and thermodynamics, materials response to applied fields, mechanics and physics of solids and soft materials. Presents mathematical concepts and materials-related problem solving skills alongside symbolic programming techniques. Symbolic algebraic computational methods, programming, and visualization techniques; topics include linear algebra, quadratic forms, tensor operations, symmetry operations, calculus of several variables, eigensystems, systems of ordinary and partial differential equations, beam theory, resonance phenomena, special functions, numerical solutions, statistical analysis, Fourier analysis, and random walks.
W. C. Carter
No required or recommended textbooks

3.017 Modelling, Problem Solving, Computing, and Visualization
______

Undergrad (Spring)
Prereq: 3.016, 6.0001, 16.66, or 12.010; 3.014, 3.022, or 3.024; or permission of instructor
Units: 2-2-8
______
Covers development and design of models for materials processes and structure-property relations. Emphasizes techniques for solving equations from models or simulating their behavior. Assesses methods for visualizing solutions and aesthetics of the graphical presentation of results. Topics include symmetry and structure, classical and statistical thermodynamics, solid state physics, mechanics, phase transformations and kinetics, statistics and presentation of data.
W. C. Carter

3.021 Introduction to Modeling and Simulation
______

Undergrad (Spring) Rest Elec in Sci & Tech
Engineering School-Wide Elective Subject.
(Offered under:1.021,3.021,10.333,22.00)
Prereq: 18.03, 3.016, or permission of instructor
Units: 4-0-8
______
Basic concepts of computer modeling and simulation in science and engineering. Uses techniques and software for simulation, data analysis and visualization. Continuum, mesoscale, atomistic and quantum methods used to study fundamental and applied problems in physics, chemistry, materials science, mechanics, engineering, and biology. Examples drawn from the disciplines above are used to understand or characterize complex structures and materials, and complement experimental observations.
M. Buehler, R. Taylor

3.022 Microstructural Evolution in Materials
______

Undergrad (Spring)
Prereq: 3.012
Units: 3-3-6
______
Covers microstructures, defects, and structural evolution in all classes of materials. Topics include solution kinetics, interface stability, dislocations and point defects, diffusion, surface energetics, grains and grain boundaries, grain growth, nucleation and precipitation, and electrochemical reactions. Lectures illustrate a range of examples and applications based on metals, ceramics, electronic materials, polymers, and biomedical materials. Explores the evolution of microstructure through experiments involving optical and electron microscopy, calorimetry, electrochemical characterization, surface roughness measurements, and other characterization methods. Investigates structural transitions and structure-property relationships through practical materials examples.
Y. Chiang, G. Beach, J. Hu

3.024 Electronic, Optical and Magnetic Properties of Materials
______

Undergrad (Spring)
Prereq: 3.012
Units: 3-3-6
______
Uses fundamental principles of quantum mechanics, solid state physics, electricity and magnetism to describe how the electronic, optical and magnetic properties of materials originate. Illustrates how these properties can be designed for particular applications, such as diodes, solar cells, optical fibers, and magnetic data storage. Involves experimentation using spectroscopy, resistivity, impedance and magnetometry measurements, behavior of light in waveguides, and other characterization methods. Uses practical examples to investigate structure-property relationships.
P. Anikeeva, G. Beach, J. Hu

3.032 Mechanical Behavior of Materials
______

Undergrad (Fall)
Prereq: Physics I (GIR); 3.016 or 18.03
Units: 3-1-8
Lecture is on-line. R class meets in 4-153. Lab: T9-1 (8-107) or R9-1 (8-107) Recitation: M1-2.30,RF1 (4-261)
______
Basic concepts of solid mechanics and mechanical behavior of materials: elasticity, stress-strain relationships, stress transformation, viscoelasticity, plasticity and fracture. Continuum behavior as well as atomistic explanations of the observed behavior are described. Examples from engineering as well as biomechanics. Lab experiments and demonstrations give hands-on experience of the physical concepts. Offers a combination of online and in-person instruction.
L. Gibson
Textbooks (Fall 2016)

3.034 Organic and Biomaterials Chemistry
______

Undergrad (Fall)
Prereq: 3.012
Units: 4-2-6
Lecture: MWF11 (4-153) Lab: T9-1 (8-107) or R9-1 (8-107) Recitation: T11 (8-119) or R11 (8-119)
______
Focuses on the chemistry and chemical structure-property relationships of soft synthetic and biologically derived materials. Topics include methods for preparing synthetic polymers by step and chain growth polymerizations; polymerization reaction kinetics; chemistry of proteins, nucleic acids, polysaccharides and lipids, and their incorporation into biomaterials and biosensors; enzymatic reactions and ligations; chemical modification and patterning of organic and inorganic surfaces using organosilane and self-assembled monolayer chemistries, radiation grafting, physisorption and microcontact printing; organic systems as templates for inorganic materials; sol gel syntheses, polymer precursor conversions, polymer vesicle naroreactors; chemical degradation of soft materials through readition, hydrolysis, and thermolysis; electroactive organic materials. Firsthand application of lecture topics through design-oriented experiments.
R. Macfarlane
No required or recommended textbooks

3.035 Problems in Materials Science and Engineering
______

Undergrad (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
3.035: TBA.
______
Staff
3.035: No textbook information available

3.036, 3.037 Problems in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
3.036: TBA.
3.037: TBA.
______
3.036: No textbook information available
3.037: No textbook information available

3.038, 3.039, 3.04 Problems in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
3.038: TBA.
3.039: TBA.
3.04: TBA.
______
For undergraduates desiring to carry on projects of their own choosing, which may be experimental, theoretical, or of a design nature. Also for undergraduate studies arranged by students or staff, which may consist of seminars, assigned reading, or laboratory projects. See UROP Coordinator for registration procedures.
Staff
3.038: No textbook information available
3.039: No textbook information available
3.04: No textbook information available

3.042 Materials Project Laboratory
______

Undergrad (Fall, Spring)
Prereq: 3.014, 3.032, or 3.044
Units: 1-6-5
Lecture: R1 (4-145) Lab: TR2-5 (4-131B)
______
Student project teams design and fabricate a working prototype using materials processing technologies (e.g. solid works 3-D design software, computer numerical controlled mill, injection molding, thermoforming, investment casting, powder processing, three-dimensional printing, physical vapor deposition) appropriate for the materials and device of interest. Goals include using MSE fundamentals in a practical application; understanding trade-offs between design, processing, and performance and cost; and fabrication of a deliverable prototype. Emphasis on teamwork, project management, communications and computer skills, with extensive hands-on work using student and MIT laboratory shops. Teams document their progress and final results by means of written and oral communication. Limited to 25.
M. Tarkanian
No required or recommended textbooks

3.044 Materials Processing
______

Undergrad (Spring)
Prereq: 3.012, 3.022
Units: 4-0-8
______
Introduction to materials processing science, with emphasis on heat transfer, chemical diffusion, and fluid flow. Uses an engineering approach to analyze industrial-scale processes, with the goal of identifying and understanding physical limitations on scale and speed. Covers materials of all classes, including metals, polymers, electronic materials, and ceramics. Considers specific processes, such as melt-processing of metals and polymers, deposition technologies (liquid, vapor, and vacuum), colloid and slurry processing, viscous shape forming, and powder consolidation.
E. Olivetti

3.046 Thermodynamics of Materials
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: 18.03, 18.034, or 3.016
Units: 4-0-8
______
The laws of thermodynamics and their application to equilibrium and the properties of materials. Foundation to treat general phenomena in materials science and engineering, including chemical reactions, magnetism, polarizability, and elasticity. Relations pertaining to multiphase equilibria as determined by a treatment of solution thermodynamics. Graphical constructions that are essential for the interpretation of phase diagrams. Electrochemical equilibria and surface thermodynamics. Aspects of statistical thermodynamics as they relate to macroscopic equilibrium phenomena.
R. Jaramillo

3.048 Advanced Materials Processing
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 3.022, 3.044
Units: 3-0-9
______
Fundamentals of materials processing. Building engineering structures from the atomic- and nano-scales to macroscopic levels. Case studies illustrating application of processing science to creation of modern metallic, ceramic, polymeric and biomaterials devices and components.
Staff

3.052 Nanomechanics of Materials and Biomaterials
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 3.032 or permission of instructor
Units: 3-0-9
______
Latest scientific developments and discoveries in the field of nanomechanics, i.e. the deformation of extremely tiny (10-9 meters) areas of synthetic and biological materials. Lectures include a description of normal and lateral forces at the atomic scale, atomistic aspects of adhesion, nanoindentation, molecular details of fracture, chemical force microscopy, elasticity of individual macromolecular chains, intermolecular interactions in polymers, dynamic force spectroscopy, biomolecular bond strength measurements, and molecular motors.
Staff

3.053[J] Molecular, Cellular, and Tissue Biomechanics
______

Undergrad (Spring)
(Same subject as2.797[J],6.024[J],20.310[J])
Prereq: 2.370 or 2.772J; 18.03 or 3.016; Biology (GIR)
Units: 4-0-8
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, A. J. Grodzinsky, K. Van Vliet

3.054 Cellular Solids: Structure, Properties, Applications
______

Undergrad (Fall)
(Subject meets with3.36)
Prereq: 3.032
Units: 2-0-10
Lecture: T9.30-11 (2-136)
______
Discusses processing and structure of cellular solids as they are created from polymers, metals, ceramics, glasses, and composites; derivation of models for the mechanical properties of honeycombs and foams; and how unique properties of honeycombs and foams are exploited in applications such as lightweight structural panels, energy absorption devices, and thermal insulation. Covers applications of cellular solids in medicine, such as increased fracture risk due to trabecular bone loss in patients with osteoporosis, the development of metal foam coatings for orthopedic implants, and designing porous scaffolds for tissue engineering that mimic the extracellular matrix. Includes modelling of cellular materials applied to natural materials and biomimicking. Offers a combination of online and in-person instruction. Students taking graduate version complete additional assignments.
L. Gibson
Textbooks (Fall 2016)

3.055[J] Biomaterials Science and Engineering
______

Undergrad (Fall)
(Same subject as20.363[J])
(Subject meets with3.963[J],20.463[J])
Prereq: 3.034, 20.110, or permission of instructor
Units: 3-0-9
Lecture: MW11-12.30 (56-614)
______
Covers, at a molecular scale, the analysis and design of materials used in contact with biological systems, and biomimetic strategies aimed at creating new materials based on principles found in biology. Topics include molecular interaction between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of materials science to problems in tissue engineering, drug delivery, vaccines, and cell-guiding surfaces. Students taking graduate version complete additional assignments.
D. Irvine, K. Ribbeck
No textbook information available

3.063 Polymer Physics
______

Undergrad (Spring)
(Subject meets with3.942)
Prereq: 3.012
Units: 4-0-8
______
The mechanical, optical, electrical, and transport properties of polymers and other types of "soft matter" are presented with respect to the underlying physics and physical chemistry of polymers and colloids in solution, and solid states. Topics include how enthalpy and entropy determine conformation, molecular dimensions and packing of polymer chains and colloids and supramolecular materials. Examination of the structure of glassy, crystalline, and rubbery elastic states of polymers; thermodynamics of solutions, blends, crystallization; liquid crystallinity, microphase separation, and self-assembled organic-inorganic nanocomposites. Case studies of relationships between structure and function in technologically important polymeric systems. Students taking graduate version complete additional assignments.
A. Alexander-Katz

3.064 Polymer Engineering
______

Undergrad (Fall)
Prereq: 3.032, 3.044
Units: 3-0-9
URL: http://web.mit.edu/course/3/3.064/www/
Lecture: MWF12 (4-145)
______
Overview of polymer material science and engineering. Treatment of physical and chemical properties, mechanical characterization, processing, and their control through inspired polymer material design.
N. Holten-Andersen
No textbook information available

3.07 Introduction to Ceramics
______

Undergrad (Fall)
Prereq: 3.012
Units: 3-0-9
Lecture: MW2.30-4 (8-119)
______
Discusses structure-property relationships in ceramic materials. Includes hierarchy of structures from the atomic to microstructural levels. Defects and transport, solid-state electrochemical processes, phase equilibria, fracture and phase transformations are discussed in the context of controlling properties for various applications of ceramics. Numerous examples from current technology.
Y. Chiang
No required or recommended textbooks

3.071 Amorphous Materials
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 3.024
Units: 3-0-9
______
Discusses the fundamental material science behind amorphous solids (non-crystalline materials). Covers formation of amorphous solids; amorphous structures and their electrical and optical properties; and characterization methods and technical applications.
J. Hu

3.072 Symmetry, Structure and Tensor Properties of Materials
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with3.60)
Prereq: 3.016 or 18.03
Units: 4-0-8
Subject Cancelled Subject Cancelled
______
Studies the underlying structures of materials and deepens understanding of the relationship between the properties of materials and their structures. Topics include lattices, point groups, and space groups in both two and three dimensions; the use of symmetry in the tensor representation of crystal properties; and the relationship between crystalline structure and properties, including transport properties, piezoelectricity, and elasticity. Students taking graduate version complete additional assignments.
R. Taylor, E. Fitzgerald

3.074 Imaging of Materials
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with3.34)
Prereq: 3.024
Units: 3-0-9
______
Principles and applications of imaging techniques for materials characterization including transmission and scanning electron microscopy and scanning probe microscopy. Topics include electron diffraction; image formation in transmission and scanning electron microscopy; diffraction and phase contrast; imaging of crystals and crystal imperfections; review of the most recent advances in electron microscopy for bio- and nanosciences; analysis of chemical composition and electronic structure at the atomic scale. Lectures, real-case studies and computer simulations.
S. Gradečak

3.080 Strategic Materials Selection
______

Undergrad (Spring)
Prereq: 3.012, 3.014, or permission of instructor
Units: 3-0-9
______
Provides a survey of methods for evaluating choice of material and explores the implications of that choice. Topics include manufacturing economics and utility analysis. Students carry out a group project selecting materials technology options based on economic characteristics.
R. Kirchain

3.081 Industrial Ecology of Materials
______

Undergrad (Fall)
(Subject meets with3.560)
Prereq: 3.012, 3.014, or permission of instructor
Units: 3-0-9
URL: http://www-dmse.mit.edu/courses/3.081/
Lecture: MW2.30-4 (8-205)
______
Covers quantitative techniques to address principles of substitution, dematerialization, and waste mining implementation in materials systems. Includes life-cycle and materials flow analysis of the impacts of materials extraction; processing; use; and recycling for materials, products, and services. Student teams undertake a case study regarding materials and technology selection using the latest methods of analysis and computer-based models of materials process. Students taking graduate version complete additional assignments.
E. Olivetti
No required or recommended textbooks

3.086 Innovation and Commercialization of Materials Technology
______

Undergrad (Spring)
(Subject meets with3.207)
Prereq: None
Units: 4-0-8
______
Covers the fundamental process of innovation through its implications on organizations and innovation ecosystems. Emphasizes historical and modern examples of innovation in materials and devices. Discusses the final implications for innovation ecosystems.
E. Fitzgerald

3.091 Introduction to Solid-State Chemistry
______

Undergrad (Fall, Spring) Chemistry
(Subject meets withES.3091)
Prereq: None
Units: 5-0-7
Credit cannot also be received for5.111,5.112,CC.5111,ES.5111,ES.5112
Lecture: MWF11 (10-250) Recitation: TR9 (36-155) or TR10 (36-155, 13-5101, 13-4101) or TR11 (1-242, 36-155, 13-5101, 13-4101) or TR12 (36-155, 13-5101, 13-3101) or TR2 (13-1143, 26-322, 26-302, 13-3101, 36-144) or TR3 (13-4101) or TR4 (13-4101) +final
______
Basic principles of chemistry and their application to engineering systems. The relationship between electronic structure, chemical bonding, and atomic order. Characterization of atomic arrangements in crystalline and amorphous solids: metals, ceramics, semiconductors, and polymers. Topical coverage of organic chemistry, solution chemistry, acid-base equilibria, electrochemistry, biochemistry, chemical kinetics, diffusion, and phase diagrams. Examples from industrial practice (including the environmental impact of chemical processes), from energy generation and storage (e.g., batteries and fuel cells), and from emerging technologies (e.g., photonic and biomedical devices).
Fall:J. Grossman
Spring:N. Holten-Andersen, R. Macfarlane
Textbooks (Fall 2016)

3.094 Materials in Human Experience
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 2-3-4
______
Examines the ways in which people in ancient and contemporary societies have selected, evaluated, and used materials of nature, transforming them to objects of material culture. Some examples: glass in ancient Egypt and Rome; sounds and colors of powerful metals in Mesoamerica; cloth and fiber technologies in the Inca empire. Explores ideological and aesthetic criteria often influential in materials development. Laboratory/workshop sessions provide hands-on experience with materials discussed in class. Subject complements 3.091. Enrollment may be limited.
H. N. Lechtman

3.14 Physical Metallurgy
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with3.40[J],22.71[J])
Prereq: 3.022, 3.032
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Focuses on the links between the processing, structure, and properties of metals and alloys. First, the physical bases for strength, stiffness, and ductility are discussed with reference to crystallography, defects, and microstructure. Second, phase transformations and microstructural evolution are studied in the context of alloy thermodynamics and kinetics. Together, these components comprise the modern paradigm for designing metallic microstructures for optimized properties. Concludes with a focus on processing/microstructure/property relationships in structural engineering alloys, particularly steels and aluminum alloys. Students taking the graduate version explore the subject in greater depth.
C. Tasan

3.15 Electrical, Optical, and Magnetic Materials and Devices
______

Undergrad (Spring)
Prereq: 3.024
Units: 4-0-8
______
Explores the relationships between the performance of electrical, optical, and magnetic devices and the microstructural characteristics of the materials from which they are constructed. Features a device-motivated approach that places strong emphasis on emerging technologies. Applications include diodes, transistors, photodetectors, solar cells (photovoltaics), displays, light emitting diodes, lasers, optical fibers and optical communications, photonic devices, magnetic data storage and spintronics.
C. A. Ross

3.152 Magnetic Materials
______

Undergrad (Fall)
(Subject meets with3.45)
Prereq: 3.024
Units: 3-0-9
Lecture: TR1-2.30 (4-149)
______
Topics include origin of magnetism in materials, magnetic domains and domain walls, magnetostatics, magnetic anisotropy, antiferro- and ferrimagnetism, magnetism in thin films and nanoparticles, magnetotransport phenomena, and magnetic characterization. Discusses a range of applications, including magnetic recording, spin-valves, and tunnel-junction sensors. Assignments include problem sets and a term paper on a magnetic device or technology. Students taking graduate version complete additional assignments.
C. Ross
Textbooks (Fall 2016)

3.153 Nanoscale Materials
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 3.024
Units: 4-0-8
______
Builds on concepts from quantum mechanics and electromagnetics to develop an understanding of the properties of materials on the nanoscale. Illustrates the promise and challenges facing the field through case studies and the survey of fabrication methods.
Y. Fink

3.154[J] Materials Performance in Extreme Environments
______

Not offered academic year 2016-2017Undergrad (Spring)
(Same subject as22.054[J])
Prereq: 3.032, 3.044
Units: 3-2-7
______
Studies the behavior of materials in extreme environments typical of those in which advanced energy systems (including fossil, nuclear, solar, fuel cells, and battery) operate. Takes both a science and engineering approach to understanding how current materials interact with their environment under extreme conditions. Explores the role of modeling and simulation in understanding material behavior and the design of new materials. Focuses on energy and transportation related systems.
R. Ballinger

3.155[J] Micro/Nano Processing Technology
______

Undergrad (Fall)
(Same subject as6.152[J])
Prereq: Permission of instructor
Units: 3-4-5
Lecture: MW2.30-4 (32-124)
______
Introduces the theory and technology of micro/nano fabrication. Lectures and laboratory sessions on basic processing techniques such as vacuum processes, lithography, diffusion, oxidation, and pattern transfer. Students fabricate MOS capacitors, nanomechanical cantilevers, and microfluidic mixers. Emphasis on the interrelationships between material properties and processing, device structure, and the electrical, mechanical, optical, chemical or biological behavior of devices. Provides background for thesis work in micro/nano fabrication. Students engage in extensive written and oral communication exercises.
L. F. Velasquez-Garcia, J. Michel
Textbooks (Fall 2016)

3.156 Photonic Materials and Devices
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with3.46)
Prereq: 3.016 or 18.03; 3.024
Units: 3-0-9
______
Optical materials design for semiconductors, dielectrics, organic and nanostructured materials. Ray optics, electromagnetic optics and guided wave optics. Physics of light-matter interactions. Device design principles: LEDs, lasers, photodetectors, solar cells, modulators, fiber and waveguide interconnects, optical filters, and photonic crystals. Device processing: crystal growth, substrate engineering, thin film deposition, etching and process integration for dielectric, silicon and compound semiconductor materials. Micro- and nanophotonic systems. Organic, nanostructured and biological optoelectronics. Assignments include three design projects that emphasize materials, devices and systems applications. Students taking graduate version complete additional assignments.
P. Anikeeva

3.18 Materials Science and Engineering of Clean Energy
______

Undergrad (Spring)
(Subject meets with3.70)
Prereq: 3.022, 3.024
Units: 3-0-9
______
Develops the materials principles, limitations, and challenges of clean energy technologies, including solar, energy storage, thermoelectrics, fuel cells, and novel fuels. Draws correlations between the limitations and challenges related to key figures of merit and the basic underlying thermodynamic, structural, transport, and physical principles, as well as to the means for fabricating devices exhibiting optimum operating efficiencies and extended life at reasonable cost. Students taking graduate version complete additional assignments.
H. Tuller, K. Van Vliet

3.19 Sustainable Chemical Metallurgy
______

Undergrad (Spring)
(Subject meets with3.50)
Prereq: 3.022
Units: 3-0-9
______
Covers principles of metal extraction processes. Provides a direct application of the fundamentals of thermodynamics and kinetics to the industrial production of metals from their ores, e.g., iron, aluminum, or reactive metals and silicon. Discusses the corresponding economics and global challenges. Addresses advanced techniques for sustainable metal extraction, particularly with respect to greenhouse gas emissions. Students taking graduate version complete additional assignments.
A. Allanore

3.20 Materials at Equilibrium
______

Graduate (Fall)
Prereq: 3.012, 3.014, 3.022, 3.024, 3.034, 3.042; or permission of instructor
Units: 5-0-10
Lecture: MW9.30-11,F10 (37-212) Recitation: R3 (13-3101) or F11 (13-5101) or F12 (13-5101) +final
______
Laws of thermodynamics: general formulation and applications to mechanical, electromagnetic and electrochemical systems, solutions, and phase diagrams. Computation of phase diagrams. Statistical thermodynamics and relation between microscopic and macroscopic properties, including ensembles, gases, crystal lattices, phase transitions. Applications to phase stability and properties of mixtures. Representations of chemical equilibria. Interfaces.
A. Allanore; A. Alexander-Katz
Textbooks (Fall 2016)

3.207 Innovation and Commercialization
______

Graduate (Spring)
(Subject meets with3.086)
Prereq: None
Units: 4-0-8
______
Explores in depth projects on a particular materials-based technology. Investigates the science and technology of materials advances and their strategic value, explore potential applications for fundamental advances, and determine intellectual property related to the materials technology and applications. Students map progress with presentations, and are expected to create an end-of-term document enveloping technology, intellectual property, applications, and potential commercialization. Lectures cover aspects of technology, innovation, entrepreneurship, intellectual property, and commercialization of fundamental technologies.
E. Fitzgerald

3.21 Kinetic Processes in Materials
______

Graduate (Spring)
Prereq: 3.012, 3.022, 3.044, or permission of instructor
Units: 5-0-10
______
Unified treatment of phenomenological and atomistic kinetic processes in materials. Provides the foundation for the advanced understanding of processing, microstructural evolution, and behavior for a broad spectrum of materials. Topics include irreversible thermodynamics; rate and transition state theory, diffusion; nucleation and phase transitions; continuous phase transitions; grain growth and coarsening; capillarity driven morphological evolution; and interface stability during phase transitions.
C. Thompson

3.22 Mechanical Behavior of Materials
______

Graduate (Spring)
Prereq: 3.032 or permission of instructor
Units: 4-0-8
URL: http://web.mit.edu/3.22/www/
______
Explores how the macroscale mechanical behavior of materials originates from fundamental, microscale mechanisms of elastic and inelastic deformation. Topics include: elasticity, viscoelasticity, plasticity, creep, fracture, and fatigue. Case studies and examples are drawn from a variety of material classes: metals, ceramics, polymers, thin films, composites, and cellular materials.
C. Tasan

3.23 Electrical, Optical, and Magnetic Properties of Materials
______

Graduate (Fall)
Prereq: 8.03, 18.03
Units: 4-0-8
Lecture: TR10-11.30 (4-231) Recitation: W2 (13-4101) or W3 (13-4101) +final
______
Origin of electrical, magnetic and optical properties of materials. Focus on the acquisition of quantum mechanical tools. Analysis of the properties of materials. Presentation of the postulates of quantum mechanics. Examination of the hydrogen atom, simple molecules and bonds, and the behavior of electrons in solids and energy bands. Introduction of the variation principle as a method for the calculation of wavefunctions. Investigation of how and why materials respond to different electrical, magnetic and electromagnetic fields and probes. Study of the conductivity, dielectric function, and magnetic permeability in metals, semiconductors, and insulators. Survey of common devices such as transistors, magnetic storage media, optical fibers.
G. Beach
Textbooks (Fall 2016)

3.31[J] Radiation Damage and Effects in Nuclear Materials
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as22.74[J])
Prereq: 22.14, 3.21, or permission of instructors
Units: 3-0-9
______
Studies the origins and effects of radiation damage in structural materials for nuclear applications. Radiation damage topics include formation of point defects, defect diffusion, defect reaction kinetics and accumulation, and differences in defect microstructures due to the type of radiation (ion, proton, neutron). Radiation effects topics include detrimental changes to mechanical properties, phase stability, corrosion properties, and differences in fission and fusion systems. Term project required.
M. Short

3.320 Atomistic Computer Modeling of Materials
______

Graduate (Spring)
Prereq: 3.022, 3.20, 3.23 or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/3.320/www/
______
Theory and application of atomistic computer simulations to model, understand, and predict the properties of real materials. Energy models: from classical potentials to first-principles approaches. Density-functional theory and the total-energy pseudopotential method. Errors and accuracy of quantitative predictions. Thermodynamic ensembles: Monte Carlo sampling and molecular dynamics simulations. Free energies and phase transitions. Fluctations and transport properties. Coarse-graining approaches and mesoscale models.
B. Kozinsky

3.33[J] Defects in Materials
______

Graduate (Fall)
(Same subject as22.73[J])
Prereq: 3.21, 3.22
Units: 3-0-9
Lecture: F11-12.30 (24-121) Recitation: F EVE (4.30-6 PM) (24-115) +final
______
Examines point, line, and planar defects in structural and functional materials. Relates their properties to transport, radiation response, phase transformations, semiconductor device performance and quantum information processing. Focuses on atomic and electronic structures of defects in crystals, with special attention to optical properties, dislocation dynamics, fracture, and charged defects population and diffusion. Examples also drawn from other systems, e.g., disclinations in liquid crystals, domain walls in ferromagnets, shear bands in metallic glass, etc.
J. Li
No textbook information available

3.34 Imaging of Materials
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with3.074)
Prereq: 3.23 or permission of instructor
Units: 3-0-9
URL: http://www-dmse.mit.edu/courses/3.34/3.34.html
______
Principles and applications of imaging techniques for materials characterization including transmission and scanning electron microscopy and scanning probe microscopy. Topics include electron diffraction; image formation in transmission and scanning electron microscopy; diffraction and phase contrast; imaging of crystals and crystal imperfections; review of the most recent advances in electron microscopy for bio- and nanosciences; analysis of chemical composition and electronic structure at the atomic scale. Lectures, real-case studies and computer simulations. Graduate students complete additional assignments.
S. Gradečak

3.35 Fracture and Fatigue
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 3.032, permission of instructor
Units: 3-0-9
______
Linear elastic and elastic-plastic fracture mechanics. Theory and asymptotic analysis of crack-tip fields. Experimental methods. Microstructural effects on fracture in metals, ceramics, polymers, thin films, biological materials, and composites. Toughening mechanisms. Crack growth resistance and creep fracture. Interface fracture mechanics. Fatigue damage and dislocation substructures in single crystals. Stress- and strain-life approach to fatigue. Fatigue crack growth models and mechanisms. Variable amplitude fatigue. Corrosion fatigue. Case studies of fracture and fatigue in structural, bioimplant, and microelectronic components. Limited to 10.
M. Dao

3.36 Cellular Solids: Structure, Properties, Applications
______

Graduate (Fall)
(Subject meets with3.054)
Prereq: 3.032 or permission of instructor
Units: 3-0-9
Lecture: TR9.30-11 (2-136)
______
Discusses processing and structure of cellular solids as they are created from polymers, metals, ceramics, glasses, and composites; derivation of models for the mechanical properties of honeycombs and foams; and how unique properties of honeycombs and foams are exploited in applications such as lightweight structural panels, energy absorption devices, and thermal insulation. Covers applications of cellular solids in medicine, such as increased fracture risk due to trabecular bone loss in patients with osteoporosis, the development of metal foam coatings for orthopedic implants, and designing porous scaffolds for tissue engineering that mimic the extracellular matrix. Includes modelling of cellular materials applied to natural materials and biomimicking. Students taking graduate version complete additional assignments.
L. Gibson
Textbooks (Fall 2016)

3.371[J] Selection and Processing of Structural Materials
______

Graduate (Fall, Spring, Summer) Can be repeated for credit; partial term
(Same subject as2.821[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: MWF9 (4-145) Recitation: TR9 (4-145)
______
Discusses selection design and processing for structural materials, including casting, forging, rolling, drawing, extrusion, powder consolidation, welding, brazing, soldering, wear, corrosion, non-destructive testing and fracture. Emphasizes the underlying science of a given process rather than a detailed description of the technique or equipment. Presented in modules; repeatable for credit one time with permission of instructor, provided three different modules are selected the second term.
T. Eagar
No required or recommended textbooks
______
Summer 2016 Description for Selection and Processing of Structural Materials
(Same subject as 2.821J) (Subject meets with 3.S171)
Prereq:Permission of instructor
Units: 3-0-9
Can be repeated for credit

Discusses selection design and processing for structural materials, including casting, forging, rolling, drawing, extrusion, powder consolidation, welding, brazing, soldering, wear, corrosion, non-destructive testing and fracture. Emphasizes the underlying science of a given process rather than a detailed description of the technique or equipment. Presented in modules; repeatable for credit one time with permission of instructor, provided three different modules are selected the second term.

T. Eager
Section: MTWThF 8:00 AM-10:00 AM Room 4-145 From 06-JUN-16 Thru 22-JUL-16

3.40[J] Modern Physical Metallurgy
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as22.71[J])
(Subject meets with3.14)
Prereq: 3.022, 3.032
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Examines how the presence of 1-, 2- and 3-D defects and second phases control the mechanical, electromagnetic and chemical behavior of metals and alloys. Considers point, line and interfacial defects in the context of structural transformations including annealing, spinodal decomposition, nucleation, growth, and particle coarsening. Concentrates on structure-function relationships, and in particular how grain size, interstitial and substitutional solid solutions, and second-phase particles impact mechanical and other properties Industrially relevant case studies illustrate lecture concepts. Students taking the graduate version explore the subject in greater depth.
C. Tasan

3.41 Colloids, Surfaces, Absorption, Capillarity, and Wetting Phenomena
______

Graduate (Spring)
Prereq: 3.20, 3.21
Units: 3-0-9
______
Integrates elements of physics and chemistry toward the study of material surfaces. Begins with classical colloid phenomena and the interaction between surfaces in different media. Discusses the mechanisms of surface charge generation as well as how dispersion forces are created and controlled. Continues with exploration of chemical absorption processes and surface design of inorganic and organic materials. Includes examples in which such surface design can be used to control critical properties of materials in applications. Addresses lastly how liquids interact with solids as viewed by capillarity and wetting phenomena. Studies how materials are used in processes and applications that are intended to control liquids, and how the surface chemistry and structure of those materials makes such applications possible.
M. Cima

3.42 Electronic Materials Design
______

Graduate (Fall)
Prereq: 3.23
Units: 3-0-9
Lecture: MW11-12.30 (3-333)
______
Extensive and intensive examination of structure-processing-property correlations for a wide range of materials including metals, semiconductors, dielectrics, and optical materials. Topics covered include defect equilibria; junction characteristics; photodiodes, light sources and displays; bipolar and field effect transistors; chemical, thermal and mechanical transducers; data storage. Emphasis on materials design in relation to device performance.
H. L. Tuller
Textbooks (Fall 2016)

3.43[J] Integrated Microelectronic Devices
______

Graduate (Fall)
(Same subject as6.720[J])
Prereq: 6.012 or 3.42
Units: 4-0-8
Lecture: MWRF10 (66-144) +final
______
Covers physics of microelectronic semiconductor devices for integrated circuit applications. Topics include semiconductor fundamentals, p-n junction, metal-oxide semiconductor structure, metal-semiconductor junction, MOS field-effect transistor, and bipolar junction transistor. Studies modern nanoscale devices, including electrostatic scaling, materials beyond Si, carrier transport from the diffusive to the ballistic regime. Emphasizes physical understanding of device operation through energy band diagrams and short-channel MOSFET device design. Includes device modeling exercises. Familiarity with MATLAB required.
D. A. Antoniadis, J. A. del Alamo, H. L. Tuller
No textbook information available

3.44 Materials Processing for Micro- and Nano-Systems
______

Graduate (Fall)
Prereq: 3.20, 3.21
Units: 3-0-9
Lecture: TR9.30-11 (4-153) +final
______
Processing of bulk, thin film, and nanoscale materials for applications in electronic, magnetic, electromechanical, and photonic devices and microsystems. Topics include growth of bulk, thin-film, nanoscale single crystals via vapor and liquid phase processes; formation, patterning and processing of thin films, with an emphasis on relationships among processing, structure, and properties; and processing of systems of nanoscale materials. Examples from materials processing for applications in high-performance integrated electronic circuits, micro-/nano-electromechanical devices and systems and integrated sensors.
C. V. Thompson
Textbooks (Fall 2016)

3.45 Magnetic Materials
______

Graduate (Fall)
(Subject meets with3.152)
Prereq: 3.23
Units: 3-0-9
Lecture: TR1-2.30 (4-149)
______
Foundation topics include magnetostatics, origin of magnetism in materials, magnetic domains and domain walls, magnetic anisotropy, reversible and irreversible magnetization processes; hard and soft magnetic materials and magnetic recording. Special topics are selected from magnetism at nanoscale (thin films, surfaces, particles); amorphous and nanocrystalline magnetic materials; electronic transport in ferromagnets including magnetoresistive, spin-valve and spin-tunnel junction sensors.
C. Ross
Textbooks (Fall 2016)

3.46 Photonic Materials and Devices
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with3.156)
Prereq: 3.23
Units: 3-0-9
______
Optical materials design for semiconductors, dielectrics and polymers. Ray optics, electromagnetic optics and guided wave optics. Physics of light-matter interactions. Device design principles: LEDs, lasers, photodetectors, modulators, fiber and waveguide interconnects, optical filters, and photonic crystals. Device processing: crystal growth, substrate engineering, thin film deposition, etching and process integration for dielectric, silicon and compound semiconductor materials. Microphotonic integrated circuits. Telecom/datacom systems. Assignments include three design projects that emphasize materials, devices and systems applications. Students taking graduate version complete additional assignments.
P. Anikeeva


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Produced: 26-SEP-2016 05:10 PMFall 2016 Course 3: Materials Science and Engineering
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Course 3: Materials Science and Engineering
Fall 2016


3.50 Sustainable Chemical Metallurgy
______

Graduate (Spring)
(Subject meets with3.19)
Prereq: 3.022 or permission of instructor
Units: 3-0-9
______
Covers principles of metal extraction processes. Provides a direct application of the fundamentals of thermodynamics and kinetics to the industrial production of metals from their ores, e.g. iron, aluminum, or reactive metals and silicon. Discusses the corresponding economics and global challenges. Addresses advanced techniques for sustainable metal extraction, particularly with respect to greenhouse gas emissions. Students taking graduate version complete additional assignments.
A. Allanore

3.53 Electrochemical Processing of Materials
______

Graduate (Spring); partial term
Prereq: 3.044
Units: 3-0-6
______
Thermodynamic and transport properties of aqueous and nonaqueous electrolytes. The electrode/electrolyte interface. Kinetics of electrode processes. Electrochemical characterization: d.c. techniques (controlled potential, controlled current), a.c. techniques (voltametry and impedance spectroscopy). Applications: electrowinning, electrorefining, electroplating, and electrosynthesis, as well as electrochemical power sources (batteries and fuel cells).
D. R. Sadoway

3.54[J] Corrosion: The Environmental Degradation of Materials
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as22.72[J])
Prereq: 3.012
Units: 3-0-9
______
Applies thermodynamics and kinetics of electrode reactions to aqueous corrosion of metals and alloys. Application of advanced computational and modeling techniques to evaluation of materials selection and susceptibility of metal/alloy systems to environmental degradation in aqueous systems. Discusses materials degradation problems in marine environments, oil and gas production, and energy conversion and generation systems, including fossil and nuclear.
R. G. Ballinger

3.560 Industrial Ecology of Materials
______

Graduate (Fall)
(Subject meets with3.081)
Prereq: 3.20 or permission of instructor
Units: 3-0-9
Lecture: MW2.30-4 (8-205)
______
Covers quantitative techniques to address principles of substitution, dematerialization, and waste mining implementation in materials systems. Includes life-cycle and materials flow analysis of the impacts of materials extraction; processing; use; and recycling for materials, products, and services. Student teams undertake a case study regarding materials and technology selection using the latest methods of analysis and computer-based models of materials process. Students taking graduate version complete additional assignments.
E. Olivetti
No required or recommended textbooks

3.57 Materials Selection, Design, and Economics
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
______
A survey of techniques for analyzing how the choice of materials, processes, and design determine properties, performance, and cost. Topics include production and cost functions, mathematical optimization, evaluation of single and multi-attribute utility, decision analysis, materials property charts, and performance indices. Students use analytical techniques to develop a plan for starting a new materials-related business.
Staff

3.60 Symmetry, Structure, and Tensor Properties of Materials
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with3.072)
Prereq: 3.016 or 18.03
Units: 4-0-8
URL: http://www-swiss.ai.mit.edu/~astark/crystal.html
Subject Cancelled Subject Cancelled
______
Studies the underlying structures of materials and deepens understanding of the relationship between the properties of materials and their structures. Topics include lattices, point groups, and space groups in both two and three dimensions; the use of symmetry in the tensor representation of crystal properties; and the relationship between crystalline structure and properties, including transport properties, piezoelectricity, and elasticity. Students taking graduate version complete additional assignments.
R. Taylor, E. Fitzgerald

3.65 Soft Matter Characterization
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 2-1-9
______
Focuses on the design and execution of advanced experiments to characterize soft materials, such as synthetic and natural polymers, biological composites, and supramolecular nanomaterials. Each week focuses on a new characterization technique explored through interactive lectures, demonstrations, and lab practicum sessions in which students gain experience in key experimental aspects of soft matter sample preparation and characterization. Among others, topics include chemical characterization, rheology and viscometry, microscopy, and spectroscopic analyses. Limited to 15.
J. Ortony

3.69 Teaching Fellows Seminar
______

Graduate (Fall) Can be repeated for credit
Prereq: None
Units: 2-0-1
TBA.
______
Provides instruction to help prepare students for teaching at an advanced level and for industry or academic career paths. Topics include preparing a syllabus, selecting a textbook, scheduling assignments and examinations, lecture preparation, "chalk and talk" vs. electronic presentations, academic honesty and discipline, preparation of examinations, grading practices, working with teaching assistants, working with colleagues, mentoring outside the classroom, pursuing academic positions, teaching through technical talks, and successful grant writing strategies.
C. Schuh
No textbook information available

3.691 Teaching Materials Science and Engineering
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 0-1-0 [P/D/F]
TBA.
______
Provides classroom or laboratory teaching experience under the supervision of faculty member(s). Students assist faculty by preparing instructional materials, leading discussion groups, and monitoring students' progress. Limited to Course 3 undergraduates selected by Teaching Assignments Committee.
G. Beach
No required or recommended textbooks

3.692 Teaching Materials Science and Engineering
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Provides classroom or laboratory teaching experience under the supervision of faculty member(s). Students assist faculty by preparing instructional materials, leading discussion groups, and monitoring students' progress. Credit arranged on a case-by-case basis and reviewed by the department. Limited to Course 3 undergraduates selected by Teaching Assignments Committee.
G. Beach
No required or recommended textbooks

3.693-3.699 Teaching Materials Science and Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
Subject Cancelled 3.693 Cancelled
Subject Cancelled 3.695 Cancelled
Subject Cancelled 3.696 Cancelled
3.697: TBA.
Subject Cancelled 3.698 Cancelled
Subject Cancelled 3.699 Cancelled
______
Laboratory, tutorial, or classroom teaching under the supervision of a faculty member. Students selected by interview. Enrollment limited by availability of suitable teaching assignments.
D. Sadoway
3.697: No required or recommended textbooks

3.70 Materials Science and Engineering of Clean Energy
______

Graduate (Spring)
(Subject meets with3.18)
Prereq: 3.20, 3.23, or permission of instructor
Units: 3-0-9
______
Develops the materials principles, limitations and challenges in clean energy technologies, including solar, energy storage, thermoelectrics, fuel cells, and novel fuels. Draws correlations between the limitations and challenges related to key figures of merit and the basic underlying thermodynamic, structural, transport, and physical principles, as well as to the means for fabricating devices exhibiting optimum operating efficiencies and extended life at reasonable cost. Students taking graduate version complete additional assignments.
H. Tuller, K. Van Vliet

3.903[J] Seminar in Polymers and Soft Matter
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as10.960[J])
Prereq: None
Units: 2-0-0 [P/D/F]
Lecture: W3-5 (56-114)
______
A series of seminars covering a broad spectrum of topics in polymer science and engineering, featuring both on- and off-campus speakers.
A. Alexander-Katz, R. E. Cohen, D. Irvine
No required or recommended textbooks

3.91 Mechanical Behavior of Polymers
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/course/3/3.91/www/
______
Influence of processing and structure on mechanical properties of synthetic and natural polymers: Hookean and entropic elastic deformation, linear viscoelasticity, composite materials and laminates, yield and fracture. Introductory subjects in solid mechanics and polymers recommended, e.g. 3.032, 3.034.
Staff

3.930 Internship Program
______

Undergrad (Summer)
Prereq: None
Units: 0-6-0 [P/D/F]
______
Provides academic credit for first approved materials science and engineering internship. For reporting requirements, consult the faculty internship program coordinator. Limited to Course 3 internship track majors.
T. Eagar
No textbook information available

3.931 Internship Program
______

Undergrad (Summer)
Prereq: 3.930
Units: 0-6-0
______
Provides academic credit for second approved materials science and engineering internship in the year following completion of 3.930. For reporting requirements consult the faculty internship program coordinator. Limited to Course 3 internship track majors.
T. Eagar
No textbook information available

3.932 Industrial Practice
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Provides academic credit to graduate students for approved work assignments at companies/national laboratories. Restricted to DMSE SM or PhD/ScD students.
D. Sadoway
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

3.94 Morphology of Polymers
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 3.063
Units: 3-0-6
______
Structure of noncrystalline, crystalline, and liquid crystalline polymers, including polymers blends, and block copolymers. Texture development from processing operations, mechanical deformation, and applied electric and magnetic fields. Hybrid organic-inorganic nano and microcomposites. Phase transformations, including classical nucleation theory and spinodal decomposition. Use of morphological characterization methods such as wide- and small-angle x-ray scattering and scanning, transmission electron microscopy and atomic force microscopy are also covered.
Staff

3.941[J] Statistical Mechanics of Polymers
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as10.668[J])
Prereq: 10.568 or permission of instructor
Units: 3-0-9
______
Concepts of statistical mechanics and thermodynamics applied to macromolecules: polymer conformations in melts, solutions, and gels; Rotational Isomeric State theory, Markov processes and molecular simulation methods applied to polymers; incompatibility and segregation in incompressible and compressible systems; molecular theory of viscoelasticity; relation to scattering and experimental measurements.
G. C. Rutledge, A. Alexander-Katz

3.942 Polymer Physics
______

Graduate (Spring)
(Subject meets with3.063)
Prereq: 3.032 or permission of instructor
Units: 4-0-8
______
The mechanical, optical, electrical, and transport properties of polymers and other types of "soft matter" are presented with respect to the underlying physics and physical chemistry of polymers and colloids in solution, and solid states. Topics include how enthalpy and entropy determine conformation, molecular dimensions and packing of polymer chains and colloids and supramolecular materials. Examination of the structure of glassy, crystalline, and rubbery elastic states of polymers; thermodynamics of solutions, blends, crystallization; liquid crystallinity, microphase separation, and self-assembled organic-inorganic nanocomposites. Case studies of relationships between structure and function in technologically important polymeric systems. Students taking graduate version complete additional assignments.
A. Alexander-Katz

3.96[J] Biomaterials: Tissue Interactions
______

Graduate (Fall)
(Same subject as 2.79[J],HST.522[J])
Prereq: Chemistry (GIR), Biology (GIR), Physics I (GIR); or permission of instructor
Units: 3-0-9
Lecture: TR2.30-4 (3-370)
______
Principles of materials science and cell biology underlying the development and implementation of biomaterials for the fabrication of medical devices/implants, including artificial organs and matrices for tissue engineering and regenerative medicine. Employs a conceptual model, the "unit cell process for analysis of the mechanisms underlying wound healing and tissue remodeling following implantation of biomaterials/devices in various organs, including matrix synthesis, degradation, and contraction. Methodology of tissue and organ regeneration. Discusses methods for biomaterials surface characterization and analysis of protein adsorption on biomaterials. Design of implants and prostheses based on control of biomaterials-tissue interactions. Comparative analysis of intact, biodegradable, and bioreplaceable implants by reference to case studies. Criteria for restoration of physiological function for tissues and organs.
I. V. Yannas, M. Spector
Textbooks (Fall 2016)

3.961[J] Design of Medical Devices and Implants
______

Graduate (Spring)
(Same subject as2.782[J],20.451[J],HST.524[J])
Prereq: Chemistry (GIR), Biology (GIR), Physics I (GIR); or permission of instructor
Units: 3-0-9
______
Solution of clinical problems by use of implants and other medical devices. Systematic use of cell-matrix control volumes. The role of stress analysis in the design process. Anatomic fit: shape and size of implants. Selection of biomaterials. Instrumentation for surgical implantation procedures. Preclinical testing for safety and efficacy: risk/benefit ratio assessment. Evaluation of clinical performance: design of clinical trials. Project materials drawn from orthopedic devices, soft tissue implants, artificial organs, and dental implants.
I. V. Yannas, M. Spector

3.963[J] Biomaterials Science and Engineering
______

Graduate (Fall)
(Same subject as20.463[J])
(Subject meets with3.055[J],20.363[J])
Prereq: 3.034, 20.110, or permission of instructor
Units: 3-0-9
Lecture: MW11-12.30 (56-614)
______
Covers, at a molecular scale, the analysis and design of materials used in contact with biological systems, and biomimetic strategies aimed at creating new materials based on principles found in biology. Topics include molecular interaction between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of materials science to problems in tissue engineering, drug delivery, vaccines, and cell-guiding surfaces. Students taking graduate version complete additional assignments.
D. Irvine, K. Ribbeck
No textbook information available

3.97[J] Cell-Matrix Mechanics
______

Graduate (Fall)
(Same subject as2.785[J],HST.523[J])
Prereq: 2.001, or 2.01 and 2.02A; Chemistry (GIR), Biology (GIR); or permission of instructor
Units: 3-0-9
Lecture: TR11-12.30 (1-371)
______
Mechanical forces play a decisive role during development of tissues and organs, during remodeling following injury as well as in normal function. A stress field influences cell function primarily through deformation of the extracellular matrix to which cells are attached. Deformed cells express different biosynthetic activity relative to undeformed cells. The unit cell process paradigm combined with topics in connective tissue mechanics form the basis for discussions of several topics from cell biology, physiology, and medicine.
I. V. Yannas, M. Spector
No required or recommended textbooks

3.971[J] Molecular, Cellular, and Tissue Biomechanics
______

Graduate (Fall)
(Same subject as2.798[J],6.524[J],10.537[J],20.410[J])
Prereq: Biology (GIR); 2.002, 2.006, 6.013, 10.301, or 10.302
Units: 3-0-9
Lecture: TR10.30-12 (2-143)
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, K. J. Van Vliet
No textbook information available

3.98 Polymer Synthetic Chemistry
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: One basic polymer chemistry subject
Units: 3-0-6
______
An examination of the fundamental reaction mechanisms and chemistry of polymerization reactions with an emphasis on the synthesis of new advanced polymers and their properties.
M. F. Rubner

Archaeology and Archaeological Science

3.981 Communities of the Living and the Dead: the Archaeology of Ancient Egypt
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-0-9
______
Examines the development of complex societies in Egypt over a 3000-year period. Uses archaeological and historical sources to determine how and why prehistoric communities coalesced into a long-lived and powerful state. Studies the remains of ancient settlements, tombs, and temples, exploring their relationships to one another and to the geopolitical landscape of Egypt and the Mediterranean world. Considers the development of advanced technologies, rise of social hierarchy, expansion of empire, role of writing, and growth of a complex economy.
K. Grossman

3.982 The Ancient Andean World
______

Undergrad (Fall) HASS Social Sciences
Prereq: None
Units: 3-0-6
Lecture: T EVE (7-10 PM) (4-153)
______
Examines development of Andean civilization which culminated in the extraordinary empire established by the Inka. Archaeological, ethnographic, and ethnohistorical approaches. Particular attention to the unusual topography of the Andean area, its influence upon local ecology, and the characteristic social, political, and technological responses of Andean people to life in a topographically "vertical" world. Characteristic cultural styles of prehistoric Andean life.
H. N. Lechtman
Textbooks (Fall 2016)

3.983 Ancient Mesoamerican Civilization
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Examines development of selected ancient Mesoamerican civilizations using archaeological and ethnohistorical evidence. Focuses on Olmec, Maya, Teotihuacan and Aztec, considering key technological, environmental, social organizational and ideological variables. Includes major group research project. Limited to 10.
D. Hosler

3.984 Materials in Ancient Societies: Ceramics
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-6-3
1st mtg Sept 6 at 9 am. Room 16-536. TBA.
______
Seminars and labs provide in-depth study of the technologies ancient societies used to produce objects from ceramic materials, including clays and mortars. Seminars cover basic ceramic materials science and engineering and relate materials selection and processing to environment, exchange, political power, and cultural values.
H. N. Lechtman, J. Meanwell
Textbooks (Fall 2016)

3.985[J] Archaeological Science
______

Undergrad (Spring) HASS Social Sciences
(Same subject as5.24[J],12.011[J])
Prereq: Chemistry (GIR) or Physics I (GIR)
Units: 3-1-5
______
Pressing issues in archaeology as an anthropological science. Stresses the natural science and engineering methods archaeologists use to address these issues. Reconstructing time, space, and human ecologies provides one focus; materials technologies that transform natural materials to material culture provide another. Topics include 14C dating, ice core and palynological analysis, GIS and other remote sensing techniques for site location, soil micromorphology and site formation, sourcing of metal artifacts, and microstructural and mechanical analyses of cementitious materials used in ancient monumental buildings.
H. N. Lechtman

3.986 The Human Past: Introduction to Archaeology
______

Undergrad (Fall) HASS Social Sciences Communication Intensive HASS
Prereq: None
Units: 3-0-9
Lecture: TR3 (4-231) Recitation: T4 (4-145) or R4 (4-145)
______
From an archaeological perspective, examines ancient human activities and the forces that shaped them. Draws on case studies from the Old and/or New World. Exposes students to various classes of archaeological data, such as stone, bone, and ceramics, that help reconstruct the past.
K. Grossman
No required or recommended textbooks

3.987 Human Evolution: Data from Palaeontology, Archaeology, and Materials Science
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-6-3
______
Examines human physical and cultural evolution over the past five million years via lectures and labs that incorporate data from human palaeontology, archaeology, and materials science. Topics include the evolution of hominin morphology and adaptations; the nature and structure of bone and its importance in human evolution; and the fossil and archaeological evidence for human behavioral and cultural evolution, from earliest times through the Pleistocene. Laboratory sessions include study of stone technology, artifacts, and fossil specimens.
K. Grossman

3.989 Materials in Ancient Societies: Ceramics Laboratory
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-6-3
______
Laboratory analysis of archaeological artifacts of ceramics. Follows on 3.984.
D. Hosler, J. Meanwell

3.990 Seminar in Archaeological Method and Theory
______

Undergrad (Fall, Spring)
Prereq: 3.985, 3.986, 21A.00
Units: 3-0-6
TBA.
______
Designed for undergraduate seniors majoring in Archaeology and Materials. Critical analysis of major intellectual and methodological developments in American archaeology, including evolutionary theory, the "New Archaeology," Marxism, formal and ideological approaches. Explores the use of science and engineering methods to reconstruct cultural patterns from archaeological data. Seminar format, with formal presentations by all students. Non-majors fulfilling all prerequisites may enroll by permission of instructors. Instruction and practice in oral and written communication provided.
D. Hosler, H. Lechtman, H. Merrick
No textbook information available

3.993 Archaeology of the Middle East
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-0-6
______
Focus on the rise of settled communities, cities, and empires and their technological achievements in various areas of the Middle East including Anatolia, the Levant, and Mesopotamia. Using archaeological and written sources, examines why such complex societies arose in this area. Considers the technological basis of these societies; the role of temples and religious hierarchies, of crafts and trade in luxury goods, of writing and bureaucracies, and of class stratification in the rise of early civilizations.
Staff

3.997 Graduate Fieldwork in Materials Science and Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of field research in materials science and engineering leading to the writing of an SM, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member.
H. Lechtman
No textbook information available

3.998 Doctoral Thesis Update Meeting
(New)
______

Graduate (Fall, Spring)
Prereq: None
Units: 0-1-0 [P/D/F]
TBA.
______
Thesis research update presentation to the thesis committee. Held the first or second academic term after successfully passing the Thesis Area Examination.
Staff
No required or recommended textbooks

3.EPE UPOP Engineering Practice Experience
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.EPE,2.EPE,3.EPE,6.EPE,10.EPE,16.EPE,22.EPE)
Prereq: 2.EPW or permission of instructor
Units: 0-0-1 [P/D/F]
TBA.
______
Provides sophomores with guided practice in finding opportunities and excelling in the world of practice. Building on the skills and relationships acquired in the Engineering Practice Workshop, students receive coaching to articulate goals, invoke the UPOP network of mentors and employers, identify and pursue opportunities and negotiate terms of their summer assignment. Students complete a 10-12 week internship, which includes filing three progress reports, conducting one informational interview, and possibly hosting a site visit by MIT staff. Returning to campus as juniors, UPOP students take part in reflective exercises that aid assimilation of learning objectives and reinforce the cognitive link between all aspects of the UPOP experience and disciplinary fields of study. Sequence begins in the spring of sophomore year and ends in the fall of junior year.
Staff
No textbook information available

3.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No textbook information available

3.S01 Special Subject in Materials Science and Engineering
______

Undergrad (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: TR11-12.30 (2-131)
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff
No textbook information available

3.S02 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S03 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S04 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S05 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer)
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S06 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer)
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S07 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S08 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer)
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S09 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer)
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S70-3.S75 Special Subject in Materials Science and Engineering
______

Graduate (Fall, IAP, Spring, Summer)
Prereq: Permission of instructor
Units arranged
3.S70: Lecture: TR11-12.30 (2-131)
3.S71: TBA.
3.S72: TBA.
3.S73: TBA.
3.S74: TBA.
3.S75: TBA.
______
Covers advanced topics in Materials Science and Engineering that are not included in the permanent curriculum.
Staff
3.S70: No textbook information available
3.S71: No textbook information available
3.S72: No textbook information available
3.S73: No textbook information available
3.S74: No textbook information available
3.S75: No textbook information available

3.S76-3.S79 Special Subject in Materials Science and Engineering
______

Graduate (Fall, IAP, Spring, Summer)
Prereq: Permission of instructor
Units arranged [P/D/F]
3.S76: TBA.
3.S77: TBA.
3.S78: TBA.
3.S79: TBA.
______
Covers advanced topics in Materials Science and Engineering that are not included in the permanent curriculum.
Staff
3.S76: No textbook information available
3.S77: No textbook information available
3.S78: No textbook information available
3.S79: No textbook information available

3.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of an SM, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member.
D. Sadoway
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

3.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Program of research leading to the writing of an SB thesis; to be arranged by the student and an appropriate MIT faculty member. Instruction and practice in oral and written communication.
Information: DMSE Academic Office
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

3.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

3.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Extended participation in work of a research group. Independent study of literature, direct involvement in group's research (commensurate with student skills), and project work under an individual faculty member. See UROP coordinator for registration procedures.
Information: DMSE Academic Office
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|3.00-3.499|3.50-3.999 plus UROP, UPOP, and Thesis|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 4: Architecture
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Course 4: Architecture
Fall 2016


Architecture Design

4.021 Introduction to Architecture Design
______

Undergrad (Fall) HASS Arts
Prereq: None
Units: 3-3-6
Credit cannot also be received for4.02A
URL: http://architecture.mit.edu/subject/fall-2016-4021
Design: MW2-5 (3-133) +final
______
Provides an introduction to the architecture design process. Develops skills that enable design creativity, thinking, representation, and development. Beginning with abstract exercises, introduces techniques for designing and developing 2-dimensional and 3-dimensional form and space in architecture.
L. Bello Bomez, A. Garcia-Abril
No textbook information available

4.022 Architecture Design Foundations
______

Undergrad (Spring)
Prereq: None
Units: 3-3-6
______
Provides the foundations for architectural design. Focuses on design methodologies, formal and spatial analysis and the translation of creative conceptual strategies into architectural design propositions. Instruction in design skills, including digital and analogue representational techniques. Preference to Course 4 majors and minors.
Architecture Design Staff

4.023 Architecture Design Studio I
______

Undergrad (Fall)
Prereq: 4.021, 4.022
Units: 0-12-12
URL: http://architecture.mit.edu/subject/fall-2016-4023
Design: TRF1-5 (7-434) +final
______
Provides instruction in architectural design and project development within design constraints including architectural program and site. Students engage the design process through various 2-dimensional and 3-dimensional media. Working directly with representational and model making techniques, students gain experience in the conceptual, formal, spatial and material aspects of architecture. Instruction and practice in oral and written communication provided. Preference to Course 4 majors and minors.
C. Abbanat, C. Parreno
No required or recommended textbooks

4.024 Architecture Design Studio II
______

Undergrad (Spring)
Prereq: 4.023, 4.401, 4.500
Units: 0-12-12
______
Provides instruction in architectural design and project development with an emphasis on social, cultural, or civic programs. Builds on foundational design skills with more complex constraints and contexts. Integrates aspects of architectural theory, building technology, and computation into the design process. Preference to Course 4 majors.
Architecture Design Staff

4.025 Architecture Design Studio III
______

Undergrad (Fall)
Prereq: 4.024, 4.440
Units: 0-12-12
URL: http://architecture.mit.edu/subject/fall-2016-4025
Design: TRF1-5 (7-434) +final
______
Provides instruction in more advanced architectural design projects. Students develop integrated design skills as they negotiate the complex issues of program, site, and form in a specific cultural context. Focuses on how architectural concepts and ideas translate into built environments that transform the public sphere. Studio designed to prepare students for graduate studies in the field. Preference to Course 4 majors.
J. Klein
No textbook information available

4.02A Introduction to Architecture Design Intensive
______

Undergrad (IAP) HASS Arts
Prereq: None
Units: 2-5-2
Credit cannot also be received for4.021
______
Provides an introduction to the architecture design process. Develops skills that enable design creativity, thinking, representation, and development. Beginning with abstract exercises, introduces techniques for designing and developing 2-dimensional and 3-dimensional form and space in architecture.
Architecture Design Staff

4.031 Design Studio: Objects and Interaction
(New)
______

Undergrad (Fall)
Prereq: None
Units: 2-4-6
URL: http://architecture.mit.edu/subject/fall-2016-4031
Lecture: TR2-5 (7-434) +final
______
Overview of design as the giving of form, order, and interactivity to the objects that define our daily life. Follows the path from project to interactive product. Covers the overall design process, preparing students for work in a hands-on studio learning environment. Emphasizes design development and constraints. Topics include the analysis of objects; interaction design and user experience; design methodologies, current dialogues in design; economies of scale vs. means; and the role of technology in design. Provides a foundation in prototyping skills such as carpentry, casting, digital fabrication, electronics, and coding.
M. Coelho
No textbook information available

4.032 Design Studio: Information and Visualization
(New)
______

Undergrad (Spring)
Prereq: None
Units: 2-4-6
______
Provides an introduction to working with information, data and visualization in a hands-on studio learning environment. Studies the history and theory of information, followed by a series of projects in which students apply the ideas directly. Progresses though basic data analysis, visual design and presentation, and more sophisticated interaction techniques. Topics include storytelling and narrative, choosing representations, understanding audiences, and the role of designers working with data.
Staff

4.091 Independent Study in Design
(New)
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No required or recommended textbooks

4.092 Independent Study in Design
(New)
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

4.093 Independent Study in Design
(New)
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.094 Independent Study in Design
(New)
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual or group basis. Registration subject to prior arrangement for subject matter and supervision by staff.
Staff
No required or recommended textbooks

4.100 Architecture Workshop: Form and Material
______

Undergrad (IAP)
Prereq: None
Units: 0-3-0 [P/D/F]
______
Intensive design and fabrication workshop in which students create models and half-size prototypes that explore the characteristics of concrete and wood. Examines the behavior of these materials and their inherent structural qualities. Studies how architectural detail can impact the perception and creation of larger built structures and environments. Lab fee. Limited to 15; preference to freshmen.
Staff

4.101 Design Studio: Introduction to Design Techniques and Technologies
______

Undergrad (Spring)
Prereq: None
Units: 2-4-6
______
Introduces core principles, techniques and technologies for design across a wide range of media in a studio environment. Explores ideas related to form, materials, tools, systems, and structures through project-based exercises. Develops familiarity with design process, critical observation, and tools for the translation of design concepts into digital and physical constructs. Utilizing traditional and contemporary tools, faculty across various design disciplines expose students to a unique cross-section of inquiry.
C. Mueller, S. Tibbits

4.105 Geometric Disciplines and Architecture Skills I
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-2-5
URL: http://architecture.mit.edu/subject/fall-2016-4105
Design: M2-5 (3-442) +final
______
Intensive introduction to architectural design tools and process, taught through a series of short exercises. Together with 4.107, covers a broad range of topics relating to the discourse of geometry as the basis of architectural design process. Focuses on projective drawings, explicit 3D modeling, and the reciprocity between representation and materialization. Lectures, workshops, and pin-ups address the architectural arguments intrinsic to geometry and its representation. Restricted to level one MArch students.
J. Lamere, B. Clifford
No required or recommended textbooks

4.107 Geometric Disciplines and Architecture Skills II
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 4.105
Units: 2-2-5
______
Intensive investigation of advanced architectural design tools and process, taught through a series of progressive exercises. Together with 4.105, covers a broad range of topics relating to the discourse of geometry as the basis of architectural design process. Focuses on contemporary digital modeling tools, including parametric and solver-based modeling and their relationship to digital fabrication. Lectures, workshops, and pin-ups address the architectural implications of simulations and innovative means of making. Restricted to first-year MArch students.
Architecture Design Staff

4.109 Materials and Fabrication for Architecture
______

Graduate (IAP)
Prereq: Permission of instructor
Units: 0-3-6
______
Provides the material system knowledge and fabrication process skills to successfully engage with all areas of the shop, from precision handwork to multi-axis computer numerically controlled (CNC) machining. Progresses through a series of basic exercises that introduce the material and workflow, concluding with more complex problems that explore opportunities and issues specific to architecture. Lab fee. Limited to 12; preference to first-year MArch students.
J. Lavallee

4.110 Design Across Scales and Disciplines
______

Undergrad (Spring) HASS Arts
(Subject meets withMAS.650)
Prereq: None
Units: 2-2-8
______
Inspired by Charles and Ray Eames' canonical Powers of Ten, explores the relationship between science and engineering through the lens of design. Examines how transformations in science and technology have influenced design thinking and vice versa. Provides interdisciplinary skills and methods to represent, model, design and fabricate objects, machines, and systems using new computational and fabrication tools. Aims to develop methodologies for design research of interdisciplinary problems. Additional work required of students taking the graduate version of the subject. Enrollment limited; preference to Course 4 minors.
N. Oxman, J. M. Yoon

4.119 Preparation for Undergraduate Architecture Design Thesis
______

Undergrad (Fall)
Prereq: 4.024
Units: 2-0-10
URL: http://architecture.mit.edu/subject/fall-2016-4119
Lecture: F10
______
Selection of thesis topic, defining method of approach, and preparation of thesis proposal for BSA degree in architecture. Weekly class meeting as well as individual conference with faculty.
J. Lamere
No textbook information available

4.120 Furniture Making Workshop
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 2-2-5
URL: http://architecture.mit.edu/subject/fall-2016-4120
Subject Cancelled Subject Cancelled
______
Provides instruction in designing and building a functional piece of furniture from an original design. Develops woodworking techniques from use of traditional hand tools to digital fabrication. Gives students the opportunity to practice design without using a building program or code. Surveys the history of furniture making and includes site visits to local collections and artists/craftsmen. Limited to 12; preference to Course 4 students.
C. Dewart

4.130 Architectural Design Theory and Methodologies
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4130
Lecture: T9-11 (5-216)
______
Studies design as an interrogative technique to examine material sciences, media arts and technology, cultural studies, computation and emerging fabrication protocols. Provides in-depth, theoretical grounding to the notion of 'design' in architecture, and to the consideration of contemporary design methodologies, while encouraging speculation on emerging design thinking. Topical focus varies with instructor. May be repeated for credit with permission of department.
M. Goulthorpe
No textbook information available

4.140[J] How to Make (Almost) Anything
______

Graduate (Fall)
(Same subject asMAS.863[J])
Prereq: Permission of instructor
Units: 3-9-6
URL: http://fab.cba.mit.edu/classes/MAS.863/
Lecture: W1-4 (E14-633) +final
______
Provides a practical hands-on introduction to digital fabrication, including CAD/CAM/CAE, NC machining, 3-D printing and scanning, molding and casting, composites, laser and waterjet cutting, PCB design and fabrication; sensors and actuators; mixed-signal instrumentation, embedded processing, and wired and wireless communications. Develops an understanding of these capabilities through projects using them individually and jointly to create functional systems.
N. Gershenfeld, J. DiFrancesco, S. Tibbits
No textbook information available

4.151 Architecture Design Core Studio I
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 0-12-9
URL: http://architecture.mit.edu/subject/fall-2016-4151
Design: TRF1-5 (STUDIO) or TRF1-5 (STUDIO) or TRF1-5 (STUDIO)
______
Establishes foundational processes, techniques and attitudes towards architectural design. Includes projects of increasing scope and complexity engaging issues of structure, circulation, program, organization, building systems, materiality and tectonics. Develops methods of representation that incorporate both analogue and digital drawings and models. First in a sequence of design subjects, which must be taken in order. Limited to first-year MArch students.
B. Clifford, W. O'Brien
No required or recommended textbooks

4.152 Architecture Design Core Studio II
______

Graduate (Spring)
Prereq: 4.151
Units: 0-12-9
______
Builds on Core I skills and expands the constraints of the architectural problem to include issues of urban site logistics, cultural and programmatic material (inhabitation and human factors), and long span structures. Two related projects introduce a range of disciplinary issues, such as working with precedents, site, sectional and spatial proposition of the building, and the performance of the outer envelope. Emphasizes the clarity of intentions and the development of appropriate architectural and representational solutions. Limited to first-year MArch students.
Architecture Design Staff

4.153 Architecture Design Core Studio III
______

Graduate (Fall)
Prereq: 4.152
Units: 0-12-9
URL: http://architecture.mit.edu/subject/fall-2016-4153
Design: TRF1-5 (STUDIO) or TRF1-5 (STUDIO) or TRF1-5 (STUDIO)
______
Interdisciplinary approach to design through studio design problems that engage the domains of building technology, computation, and the cultural/historical geographies of energy. Uses different modalities of thought to examine architectural agendas for 'sustainability'; students position their work with respect to a broader understanding of the environment and its relationship to society and technology. Students develop a project with a comprehensive approach to programmatic organization, energy load considerations, building material assemblies, exterior envelope and structure systems. Limited to second-year MArch students.
S. Kennedy, A. Anmahian, C. Banon
No required or recommended textbooks

4.154 Architecture Design Option Studio
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 4.153
Units: 0-10-11
URL: http://architecture.mit.edu/subjects
Design: TRF1-5 (STUDIO) or TRF1-5 (STUDIO)
______
Offers a broad range of advanced-level investigations in architectural design in various contexts, including international sites. Integrates theoretical and technological discourses into specific topics. Studio problems may include urbanism and city scale strategies, habitation and urban housing systems, architecture in landscapes, material investigations and new production technologies, programmatic and spatial complex building typologies, and research centered studies. Mandatory lottery process.
Architecture Design Staff
No required or recommended textbooks

4.162 Introductory Urban Design Studio
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 0-10-11
URL: http://architecture.mit.edu/subject/fall-2016-4162
Design: TR EVE (1-6 PM) (STUDIO)
______
Project-based introduction to urban observation, research, analysis, and design. Focuses on urban elements, urban and architectural interventions, and landscape in existing cities. Emphasizes city form, sustainability, and social conditions. Projects require both conventional and digital techniques. Preference to Urbanism SMArchS students.
M. Mazereeuw, A. Berger, F. Masoud
No required or recommended textbooks

4.163[J] Urban Design Studio
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as11.332[J])
Prereq: 4.162 or permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4163
Design: TR EVE (1-6 PM) (STUDIO)
______
The design of urban environments. Strategies for change in large areas of cities, to be developed over time, involving different actors. Fitting forms into natural, man-made, historical, and cultural contexts; enabling desirable activity patterns; conceptualizing built form; providing infrastructure and service systems; guiding the sensory character of development. Involves architecture and planning students in joint work; requires individual designs or design and planning guidelines.
M. Mazereeuw, A. Berger, F. Masoud
No textbook information available

4.173[J] Beijing Urban Design Studio
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as11.307[J])
Prereq: Permission of instructor
Units: 0-18-0
TBA.
______
Design studio that includes architects and city planners working in teams on a contemporary development project of importance in China. Students analyze conditions, explore alternatives, and synthesize architecture, city design, and implementation plans. Lectures and brief study tours expose students to history and contemporary issues of urbanism in China. Offered every other summer in residence at Tsinghua University, Beijing, involving students and faculty from both schools. Limited to 10.
D. Frenchman, C. Zegras
No textbook information available

4.180 Architectural Design Workshop
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: 4.023 or permission of instructor
Units arranged
______

4.181 Architectural Design Workshop
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4181
1st mtg Sept 7 at 2-5 pm. N51-1st floor (poplab). TBA.
______
No textbook information available

4.182 Architectural Design Workshop
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4182
TBA.
______
No textbook information available

4.183-4.185 Architectural Design Workshop
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
4.183: URL: http://architecture.mit.edu/subject/fall-2016-4183
4.184: URL: http://architecture.mit.edu/subject/fall-2016-4184
4.183: 1st mtg Sept 7 at 5 pm. Room 10-471. TBA.
4.184: 1st mtg Sept 7 at 4 pm. Room 5-232. Design: TBA
______
Addresses design inquiry in a studio format. In-depth consideration of selected issues of the built world. The problem may be prototypical or a particular aspect of a whole project, but is always interdisciplinary in nature.
Architecture Design Staff
4.183: No textbook information available
4.184: No textbook information available

4.189 Preparation for MArch Thesis
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-1-5
TBA.
______
Preparatory research development leading to a well-conceived proposition for the MArch design thesis. Students formulate a cohesive thesis argument and critical project using supportive research and case studies through a variety of representational media, critical traditions, and architectural/artistic conventions. Group study in seminar and studio format, with periodic reviews supplemented by conference with faculty and a designated committee member for each individual thesis. Restricted to MArch students.
Architecture Design Staff
No textbook information available

4.190 Practical Experience in Architecture
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 0-0-3 [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4190
See advisor. TBA.
______
Practical experience through summer internships secured by the student in the field of architecture, urbanism, digital design, art, or building technology. Registration limited to two summers. Restricted to Course 4 students
Staff
No required or recommended textbooks

4.191 Independent Study in Architecture Design
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.192 Independent Study in Architecture Design
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

4.193 Independent Study in Architecture Design
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.194 Independent Study in Architecture Design
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual or group basis. Registration subject to prior arrangement for subject matter and supervision by staff.
Architecture Design Staff
No required or recommended textbooks

4.S00 Special Subject: Design
(New)
______

Undergrad (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: permission of instructor
Units arranged
______
Seminar or lecture on a topic in design that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Staff

4.S02 Special Subject: Design
(New)
______

Graduate (Fall) Can be repeated for credit
Prereq: None
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4s02
Lecture: TBA
______
Seminar or lecture on a topic in design that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Staff
No textbook information available

4.S10 Special Subject: Architecture Design
______

Undergrad (Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

4.S11 Special Subject: Architecture Design
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
______

4.S12 Special Subject: Architecture Design
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.S13 Special Subject: Architecture Design
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.S14 Special Subject: Architecture Design
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Seminar or lecture on a topic in architecture design that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Architecture Design Staff


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Produced: 26-SEP-2016 05:10 PMFall 2016 Course 4: Architecture
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Course 4: Architecture
Fall 2016


Architecture Studies

4.210 Precedents in Critical Practice
______

Graduate (Fall)
Prereq: None
Units: 3-0-6
URL: http://architecture.mit.edu/subject/fall-2016-4210
Lecture: W2-5 (9-451) +final
______
Through formal analysis and discussion of historical and theoretical texts, seminar produces a map of contemporary architectural practice. Examines six pairs of themes in terms of their recent history: city and global economy, urban plan and map of operations, program and performance, drawing and scripting, image and surface, and utopia and projection. Restricted to year-one MArch students.
A. Miljacki
No required or recommended textbooks

4.211[J] The Once and Future City
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Humanities Communication Intensive HASS
(Same subject as11.016[J])
Prereq: None
Units: 3-0-9
______
Examines the evolving structure of cities, the dynamic processes that shape them, and the significance of a city's history for its future development. Develops the ability to read urban form as an interplay of natural processes and human purposes over time. Field assignments in Boston provide the opportunity to use, develop, and refine these concepts. Enrollment limited.
A. Spirn

4.213[J] Ecological Urbanism Seminar
______

Graduate (Fall)
(Same subject as11.308[J])
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4213
Lecture: M2-5 (10-401)
______
Examines the urban environment as a natural phenomenon, human habitat, medium of expression, and forum for action. Subject has two related, major themes: how ideas of nature influence the way cities are perceived, designed, built, and managed; and how natural processes and urban form interact and the consequences of these for human health safety and welfare. Enrollment limited.
A. Spirn
Textbooks (Fall 2016)

4.214[J] Water, Landscape and Urban Design
______

Not offered academic year 2017-2018Graduate (Spring) Can be repeated for credit
(Same subject as11.314[J])
Prereq: Permission of instructor
Units: 3-3-6
______
Workshop surveys how water affects the design of buildings, landscapes and cities in aesthetic, functional and symbolic ways. Combines the systematic study of water issues with urban design projects in South Asia and the US. Covers topics such as rainwater harvesting, water use efficiency, wastewater reuse, stormwater management, floodplain design, constructed wetlands, and waterfront development. Students work together to integrate these design concepts at the site, urban, and international scales. Limited to 15.
J. Wescoat

4.215[J] Sensing Place: Photography as Inquiry
______

Graduate (Fall)
(Same subject as11.309[J])
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4215
Lecture: W EVE (2-6 PM) (10-485)
______
Explores photography as a disciplined way of seeing, of investigating urban landscapes and expressing ideas. Readings, observations, and photographs form the basis of discussions on light, detail, place, poetics, narrative, and how photography can inform design and planning. Enrollment limited.
A. Spirn
Textbooks (Fall 2016)

4.216[J] Landscape and Urban Heritage Conservation
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
(Same subject as11.316[J])
Prereq: Permission of instructor
Units: 3-3-6
______
Focuses on cultural landscape history, theory, and heritage issues and projects in the Indo-Islamic realm. Landscape and urban heritage inquiry go beyond monuments to encompass sites, cites, and regions. Combines the study of conservation theory and practice with an exploration of active urban landscape planning and design projects. Limited to 15.
J. Wescoat

4.217[J] Disaster Resilient Design
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as11.315[J])
Prereq: None
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Seminar examines the linkages between natural hazards and environmental design. Engages theoretical debates about landscapes of risk, vulnerability, and resilience. Participants generate proposals for disaster resilience through combinations of retrofit, reconstruction, resettlement, commemorative, and anticipatory design. Methods include rapid bibliographic search, risk analysis, landscape synthesis, and comparative international methods. Projects vary and may focus on current crises or involve collaboration with the Aga Khan Development Network and other humanitarian organizations. Limited to 15.
J. Wescoat

4.221 Architecture Studies Colloquium
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-1-3
URL: http://architecture.mit.edu/subject/fall-2016-4221
Lecture: R9-11 (3-133)
______
Series of open lectures, presented as an introduction to the diverse academic and creative community of MIT and the region, at which discipline groups of the SMArchS program converge and exchange ideas. Organized thematically, guest speakers from cultural and scientific fields present viewpoints in areas of emerging interest within design, building technology, architectural computation, history, and art. Encourages discourse with speakers and among students from different disciplines. Students initiate online debates among their peers and respond to an evolving series of discussions resulting in publication.
R. Ghosn, T. Hyde, S. Kennedy
No required or recommended textbooks

4.222 Professional Practice
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-3
URL: http://architecture.mit.edu/subject/fall-2016-4222
Lecture: F9-12 (1-135)
______
Gives a critical orientation towards a career in architectural practice. Uses historical and current examples to illustrate the legal, ethical and management concepts underlying the practice of architecture. Emphasis on facilitating design excellence and strengthening connections between the profession and academia.
A. Anmahian
No required or recommended textbooks

4.225 Urban Design Theory
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
URL: http://architecture.mit.edu/subject/fall-2016-4225
Lecture: MW11-12.30 (9-450A) +final
______
Introduces theories, concepts and precedents in urban design. Emphasizes traditional, modern and contemporary values and approaches to urban design. Research projects required. Preference to Urbanism SMArchS students.
M. Dennis
No textbook information available

4.227 Landscapes of Energy
(New)
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4227
Lecture: T9-12 (10-401)
______
Spatializes large technological systems of energy, analyzes existing and speculative energy visions, and imagines energy futures in relation to concerns of ecology, politics, and aesthetics. Identifies different scales of thinking about the territory of energy from that of environmental systems, to cities, regions, and global landscapes. Readings and students' research projects draw on critical geography, history of technology, environmental history to synthesize energy attributes within the design disciplines.
R. Ghosn
No required or recommended textbooks

4.230[J] SIGUS Workshop
______

Graduate (Fall, IAP) Can be repeated for credit
(Same subject as11.468[J])
(Subject meets with4.231)
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4230
Lecture: W EVE (5-6.30 PM) (2-103)
______
No required or recommended textbooks

4.231 SIGUS Workshop
______

Undergrad (Fall, IAP) Can be repeated for credit
(Subject meets with4.230[J],11.468[J])
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4230
Lecture: W EVE (5-6.30 PM) (2-103)
______
Interdisciplinary projects and interactive practices in urban settlement issues as investigated by MIT's SIGUS (Special Interest Group in Urban Settlements), with a focus on developing countries throughout the world. Participation by guest practitioners. Additional work required of students taking the graduate version.
R. Goethert
No required or recommended textbooks

4.232[J] The New Global Planning Practitioner
______

Graduate (Spring)
(Same subject as11.444[J])
(Subject meets with4.233)
Prereq: Permission of instructor
Units: 3-0-6
______
Considers a new interdisciplinary paradigm of practice that regards dialogue among practitioners and users essential for efficacious and creative design and planning process. Focuses on non-traditional client groups: communities, the poor, and the generally excluded middle-income. Explores key issues confronting development practitioners, with stress on practical exercises drawn from current national and international case studies; e.g., an investigative comparison of cities or tools in coping with impending rapid and massive growth and expansion. Engages those with a design and community service orientation. Additional work required of students taking the graduate version.
R. Goethert

4.233 The New Global Planning Practitioner
______

Undergrad (Spring)
(Subject meets with4.232[J],11.444[J])
Prereq: Permission of instructor
Units: 3-0-6
______
Considers a new interdisciplinary paradigm of practice that regards dialogue among practitioners and users essential for efficacious and creative design and planning process. Focuses on non-traditional client groups: communities, the poor, and the generally excluded middle-income. Explores key issues confronting development practitioners, with stress on practical exercises drawn from current national and international case studies; e.g., an investigative comparison of cities or tools in coping with impending rapid and massive growth and expansion. Engages those with a design and community service orientation. Additional work required of students taking the graduate version.
R. Goethert

4.236[J] Structuring Low-Income Housing Projects in Developing Countries
______

Graduate (Fall)
(Same subject as11.463[J])
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4236
Lecture: R9-12 (1-375) +final
______
Examines dynamic relationship among key actors: beneficiaries, government, and funder. Emphasis on cost recovery, affordability, replicability, user selection, and project administration. Extensive case examples provide basis for comparisons.
R. Goethert
No required or recommended textbooks

4.240[J] Urban Design Skills: Observing, Interpreting, and Representing the City
______

Graduate (Fall)
(Same subject as11.328[J])
Prereq: None
Units: 4-2-9
URL: http://architecture.mit.edu/subject/fall-2016-4240
Lecture: F9-1 (10-485) Recitation: W EVE (6-9 PM) (10-485)
______
Introduces methods of recording, evaluating, and representing the urban environment. Through visual observation, field analysis, measurements, interviews, and other means, students draw on their senses and develop their ability to deduce, conclude, question, and test conclusions about how the environment is used and valued. Using representational tools such as drawing, photographing, computer modeling and desktop publishing, students communicate what they observe along with their impressions and design ideas. Intended as a foundation for future studio work in urban design. Includes design-based projects.
E. Ben-Joseph
No required or recommended textbooks

4.241[J] The Making of Cities
______

Graduate (Spring)
(Same subject as11.330[J])
(Subject meets with4.251)
Prereq: 4.252 or 11.001
Units arranged
______
Examines the complex development of cities through history by tracing a diachronic accumulation of forms and spaces in specific cities, and showing how significant ideas were made manifest across distinct geographies and cultures. Emphasizes how economic, spiritual, political, geographic and technological forces have simultaneously shaped and, in turn, been influenced by the city. Additional work required of students taking graduate version.
L. Jacobi, R. Segal

4.244[J] Urban Design Seminar: Perspectives on Contemporary Practice
______

Graduate (Spring)
(Same subject as11.333[J])
Prereq: None
Units: 2-0-7
______
Examines innovations in urban design practice occurring through the work of leading practitioners in the fields of architecture, landscape architecture, and urban planning. Features lectures by major national and global practitioners in urban design. Projects and topics vary based on term and speakers but may cover architectural urbanism, landscape and ecology, arts and culture, urban design regulation and planning agencies, and citywide and regional design. Focuses on analysis and synthesis of themes discussed in presentations and discussions.
Staff

4.247[J] Urban Design Ideals and Action
______

Graduate (Spring)
(Same subject as11.337[J])
Prereq: 11.301 or permission of instructor
Units: 2-0-7
______
Examines the relationship between urban design ideals, urban design action, and the built environment through readings, discussions, presentations, and papers. Analyzes the diverse design ideals that influence cities and settlements, and investigates how urban designers use them to shape urban form. Provides a critical understanding of the diverse formal methods used to intervene creatively in both developed and developing contexts, especially pluralistic and informal built environments.
B. Ryan

4.250[J] Introduction to Urban Design and Development
______

Undergrad (Fall) HASS Humanities
(Same subject as11.001[J])
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4250
Lecture: MW11-12.30 (2-105) +final
______
Examines the evolving structure of cities and the way that cities, suburbs, and metropolitan areas can be designed and developed. Surveys the ideas of a wide range of people who have addressed urban problems. Stresses the connection between values and design. Demonstrates how physical, social, political and economic forces interact to shape and reshape cities over time.
L. Vale
No required or recommended textbooks

4.251 The Making of Cities
______

Undergrad (Spring)
(Subject meets with4.241[J],11.330[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Examines the complex development of cities through history by tracing a diachronic accumulation of forms and spaces in specific cities, and showing how significant ideas were made manifest across distinct geographies and cultures. Emphasizes how economic, spiritual, political, geographic and technological forces have simultaneously shaped and, in turn, been influenced by the city. Additional work required of students taking graduate version.
L. Jacobi, R. Segal

4.252[J] Introduction to Urban Design and Development
______

Graduate (Fall)
(Same subject as11.301[J])
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4252
Lecture: TR9.30-11 (9-354)
______
Examines both the structure of cities and ways they can be changed. Includes historical forces that have produced cities, models of urban analysis, contemporary theories of urban design, implementation strategies. Core lectures supplemented by discussion sessions focusing on student work and field trips. Guest speakers present cases involving current projects illustrating the scope and methods of urban design practice.
D. Frenchman
No required or recommended textbooks

4.253[J] Urban Design Politics
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as11.302[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Examines ways urban design contributes to distribution of political power and resources in cities. Investigates the nature of relations between built form and political purposes through close study of a wide variety of situations where public sector design commissions and planning processes have been clearly motivated by political pressures. Lectures and discussions focus on specific case studies of 20th-century government-sponsored designs carried out under diverse regimes in the US, Europe, and elsewhere.
L. Vale

4.254[J] Real Estate Development Studio: Complex Urban Projects
______

Graduate (Spring)
(Same subject as11.303[J])
Prereq: Permission of instructor
Units: 6-0-12
______
Focuses on the synthesis of projects for the real estate development industry, including the integration of physical design and programming with finance and marketing. Interdisciplinary student teams analyze how to maximize value in large-scale, mixed use projects in the process of preparing professional development proposals, involving sites in US cities and internationally. Reviews emerging real estate products and innovative developments to provide a foundation for studio work. Two major projects are interspersed with lectures, field trips, and short sketch exercises. Integrates skills and knowledge in the MSRED program; also open to other students interested in real estate development.
D. Frenchman, P. Roth

4.255[J] Site and Environmental Systems Planning
______

Graduate (Spring)
(Same subject as11.304[J])
Prereq: Permission of instructor
Units: 6-0-9
______
Introduces a range of practical approaches involved in evaluating and planning sites within the context of natural and cultural systems. Develops the knowledge and skills to analyze and plan a site for development through exercises and an urban design project. Topics include land inventory, urban form, spatial organization of uses, parcelization, design of roadways, grading, utility systems, off-site impacts, and landscape architecture.
M. A. Ocampo

4.264[J] Advanced Seminar in Landscape and Urbanism
______

Graduate (Spring)
(Same subject as11.334[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Explores theories, practices, and emerging trends in the fields of landscape architecture and urbanism, such as systemic design, landscape urbanism, engineered nature, drosscapes, urban biodiversity, urban mobility, megaregions, and urban agriculture. Lectures, readings, and guest speakers present a wide array of multi-disciplinary topics, including current works from P-REX lab. Students conduct independent and group research that is future-oriented.
A. Berger

4.270 Innovation for Humanitarian Assistance and Disaster Relief
(New)
______

Graduate (Spring)
Prereq: None
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Explores innovative solutions for large-scale disaster relief and humanitarian assistance (HADR) efforts. Uses case studies and interactive exercises to provide an overview of HADR activities, including generalized goals, operating environments, response communities, and technical challenges. Hands-on exercises emphasize the importance of system-oriented, sustainable design. Topics include sensing, communications, power systems, data analysis and design.
M. Mazereeuw

4.280 Undergraduate Architecture Internship
______

Undergrad (IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Students work in an architect's office to gain experience, improve skills, and see the inner workings of an everyday architectural practice. Internships possible in all sizes of firms and in public and nonprofit agencies. During IAP, a full-time, 4-week internship is required; maximum IAP credit, 6 units.
Architecture Design Staff

4.287 Graduate Architecture Internship
______

Graduate (IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Work in an architect's office to gain experience, improve skills, and see the inner workings of an everyday architectural practice. Internships possible in all sizes of firms and in public and nonprofit agencies. During IAP, a full-time, 4-week internship is required; maximum IAP credit, 6 units.
Architecture Design Staff

4.288 Preparation for SMArchS Thesis
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4288
Design: M2-5 (1-132) or T EVE (4-7 PM) (1-242) or F9 (5-216) or TBA
______
Students select thesis topic, define method of approach, and prepare thesis proposal for SMArchS degree. Faculty supervision on an individual or group basis. Intended for SMArchS program students prior to registration for 4.ThG.
T. Nagakura, M. Dennis, M. Goulthorpe
No textbook information available

4.291 Independent Study in Architecture Studies
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.292 Independent Study in Architecture Studies
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

4.293 Independent Study in Architecture Studies
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.294 Independent Study in Architecture Studies
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual or group basis. Registration subject to prior arrangement for subject matter and supervision by staff.
Architecture Studies Staff
No required or recommended textbooks

4.299 Summer Research Topics
______

Graduate (Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Supplementary summer work on individual basis. Registration subject to prior arrangement for subject matter and supervision by staff.
Staff
No textbook information available

4.S20 Special Subject: Architecture Studies
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

4.S21 Special Subject: Architecture Studies
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
______

4.S22 Special Subject: Architecture Studies
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.S23 Special Subject: Architecture Studies
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.S24 Special Subject: Architecture Studies
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Seminar or lecture on a topic in architecture studies that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Architecture Staff

4.S25 Special Subject: Urban Housing
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in urban housing that is not covered in the regular architecture curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Architecture Staff

4.S26 Special Subject: City Form
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in city form that is not covered in the regular architecture curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Architecture Staff

4.S27 Special Subject: Urban Design
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in urban design that is not covered in the regular Architecture curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Architecture Staff


left arrow|Architecture Design|Architecture Studies|Art, Culture and Technology|Building Technology|Computation|History, Theory and Criticism of Architecture and Art|Thesis and UROP|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 4: Architecture
Registrar Home | Registrar Search:
 
  MIT Course Picker | MIT Course Planner     
Home | Subject Search | Help | Symbols Help | Pre-Reg Help | Final Exam Schedule
 

Course 4: Architecture
Fall 2016


Art, Culture and Technology

4.301 Introduction to Artistic Experimentation
______

Undergrad (Fall, Spring) HASS Arts
Prereq: None
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4301
Lecture: TR2-5 (E15-207)
______
Introduces artistic practice and critical visual thinking through three studio-based projects using different scales and mediafor instance, "Body Extension," "Shaping Time," Public Making," and/or 'Networked Cultures." Each project concludes with a final presentation and critique. Students explore sculptural, architectural, performative artistic methods; video and sound art; site interventions and strategies for artistic engagement in the public realm. Lectures, screenings, guest presentations, field trips, readings, and debates supplement studio practice. Also introduces students to the historic, cultural, and environmental forces affecting both the development of an artistic vision and the reception of a work of art. Limited to 20.
A. Aksamija
No required or recommended textbooks

4.302 Foundations in Art, Design, and Spatial Practices
______

Undergrad (Spring)
Prereq: 4.021 or 4.02A
Units: 3-3-6
______
Develops an introductory foundation in artistic practice and its critical analysis, and develops artistic approaches and methods by drawing analogies to architectural thinking, urbanism, and design practice. Covers how to communicate ideas and experiences on different scales and through two-dimensional, three-dimensional, and time-based media in new genres. Uses artistic methods that engage the public realm through spatial, sculptural, performative, and process-oriented practices. Instruction components include video screenings, guest lectures, visiting artist presentations, and field trips. Instruction and practice in written and oral communication provided. Enrollment limited; preference to Course 4 majors and minors.
A. Aksamija

4.307 Art, Architecture, and Urbanism in Dialogue
______

Undergrad (Fall)
(Subject meets with4.308)
Prereq: 4.301, 4.302, or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4307
Lecture: TR9.30-12.30 (E15-283A)
______
Initiates a dialogue between architecture, urbanism, and contemporary art by focusing on the work of practitioners who intertwine the three disciplines in a critical spatial practice. Investigates themes and works ranging from early modernist practices to the contemporary and research based. Lectures, screenings, readings, and discussions with guests and faculty contribute to the development of group and individual projects and their presentation. Additional work required of students taking graduate version. Limited to 20.
T. Putrih
No required or recommended textbooks

4.308 Art, Architecture, and Urbanism in Dialogue
______

Graduate (Fall)
(Subject meets with4.307)
Prereq: Permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4307
Lecture: TR9.30-12.30 (E15-283A)
______
Initiates a dialogue between architecture, urbanism, and contemporary art by focusing on the work of practitioners who intertwine the three disciplines in a critical spatial practice. Investigates themes and works ranging from early modernist practices to the contemporary and research based. Lectures, screenings, readings, and discussions with guests and faculty contribute to the development of group and individual projects and their presentation. Additional work required of students taking graduate version. Limited to 20.
T. Putrih
No required or recommended textbooks

4.312 Advanced Studio on the Production of Space
______

Undergrad (Fall) HASS Arts Can be repeated for credit
(Subject meets with4.313)
Prereq: 4.301, 4.302, or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4312
Lecture: MW9.30-12.30 (E15-001)
______
No required or recommended textbooks

4.313 Advanced Studio on the Production of Space
______

Graduate (Fall) Can be repeated for credit
(Subject meets with4.312)
Prereq: Permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4312
Lecture: MW9.30-12.30 (E15-001)
______
Introduces historical and contemporary spatial concepts from various cultures and geo-political settings, and examines how they relate to artistic process and production. Explores the relational qualities of spatial concepts and reflects on their producers and proponents; investigates the notion of utopian, dystopian and heterotopian space, inner and outer space, the void, the vacuum, the in-between, and "real" versus "virtual" space. Lectures, readings, screenings, presentations, and guest speakers from various disciplines support the development of individual and collective projects. Additional work required of students taking the graduate version. Limited to 20.
G. Urbonas, N. Bojic
No required or recommended textbooks

4.314 Advanced Workshop in Artistic Practice and Transdisciplinary Research
______

Undergrad (Spring) HASS Arts Can be repeated for credit
(Subject meets with4.315)
Prereq: 4.301, 4.302, or permission of instructor
Units: 3-3-6
______

4.315 Advanced Workshop in Artistic Practice and Transdisciplinary Research
______

Graduate (Spring) Can be repeated for credit
(Subject meets with4.314)
Prereq: Permission of instructor
Units: 3-3-6
______
Examines artistic practice as a form of critical inquiry and knowledge production. Offers opportunity to develop art as a means for addressing the social, cultural, and ecological consequences of technology, to build bridges between industry and culture, and to challenge the boundaries between public and private, and human and non-human. Provides instruction in evaluating models of experimentation, individual research, and collaboration with other disciplines in the arts, culture, science, and technology. Supports the development of individual and collective artistic research projects. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff

4.320 Introduction to Sound Creations
______

Undergrad (Spring) HASS Arts
(Subject meets with4.321)
Prereq: None
Units: 3-3-6
______
Develops a critical awareness of how sound art as a field for artistic exploration is performed, produced, and distributed. Explores contemporary and historical practices that emerge outside of purely musical environments and investigates specific compositional developments of post-war modernity and electro-acoustic music, as well as non-musical disciplines related to the psychophysics of hearing and listening. Lectures, screenings, readings, and discussions with guests and faculty contribute to the development of group and individual projects. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff

4.321 Introduction to Sound Creations
______

Graduate (Spring)
(Subject meets with4.320)
Prereq: None
Units: 3-3-6
______
Develops a critical awareness of how sound art as a field for artistic exploration is performed, produced, and distributed. Explores contemporary and historical practices that emerge outside of purely musical environments and investigates specific compositional developments of post-war modernity and electro-acoustic music, as well as non-musical disciplines related to the psychophysics of hearing and listening. Lectures, screenings, readings, and discussions with guests and faculty contribute to the development of group and individual projects. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff

4.322 Introduction to Three-Dimensional Art Work
______

Undergrad (Fall) HASS Arts
(Subject meets with4.323)
Prereq: None
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4322
Lecture: TR9.30-12.30 (E15-207)
______
Explores three-dimensional art work, including sculptures and installations, from design to model to finished piece. Addresses challenges associated with design and fabrication, process, context, and relationships between objects, the body, and physical or cultural environments. Lectures, screenings, field trips, readings, and debates supplement studio practice. Additional work required of students taking the graduate version. Limited to 20.
A. Aksamija
No required or recommended textbooks

4.323 Introduction to Three-Dimensional Art Work
______

Graduate (Fall)
(Subject meets with4.322)
Prereq: None
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4322
Lecture: TR9.30-12.30 (E15-207)
______
Explores three-dimensional art work, including sculptures and installations, from design to model to finished piece. Addresses challenges associated with design and fabrication, process, context, and relationships between objects, the body, and physical or cultural environments. Lectures, screenings, field trips, readings, and debates supplement studio practice. Additional work required of students taking the graduate version. Limited to 20.
A. Aksamija
No required or recommended textbooks

4.330 Introduction to Networked Cultures and Participatory Media
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Arts
(Subject meets with4.331)
Prereq: None
Units: 3-3-6
Subject Cancelled Subject Cancelled
______

4.331 Introduction to Networked Cultures and Participatory Media
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.330)
Prereq: None
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Provides an overview of participatory art practices, early net art, net activism, and current online practices in art and culture. Explores the cultural, social, and political impacts of mediated communication and examines how online communications have altered the way in which collaboration occurs, changes notions of authorship, and gives rise to collectives. Incorporates implementation, critique, and design exercises and experiments, developing skills in media literacy and communication. Lectures, screenings, readings, and discussions with guests and faculty lead to the development of group and individual projects. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff

4.332 Advanced Seminar in Networked Cultures and Participatory Media
______

Undergrad (Spring) HASS Arts
(Subject meets with4.333)
Prereq: 4.330 or permission of instructor
Units: 3-3-6
______
Provides skills in media literacy and communications necessary to create networked platforms and participatory media. Explores new and emergent critical platforms and strategies, such as independent and alternative media, hybrid TV, blogs, and other social media. Incorporates implementation, critique, and discussion of design exercises and experiments. Lectures, screenings, readings, and discussions with guests and faculty lead to the development of group and individual projects. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff

4.333 Advanced Seminar in Networked Cultures and Participatory Media
______

Graduate (Spring)
(Subject meets with4.332)
Prereq: 4.330, 4.331, or permission of instructor
Units: 3-3-6
______
Provides skills in media literacy and communications necessary to create networked platforms and participatory media. Explores new and emergent critical platforms and strategies, such as independent and alternative media, hybrid TV, blogs, and other social media. Incorporates implementation, critique, and discussion of design exercises and experiments. Lectures, screenings, readings, and discussions with guests and faculty lead to the development of group and individual projects. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff

4.341 Introduction to Photography and Related Media
______

Undergrad (Fall, Spring) HASS Arts
(Subject meets with4.342)
Prereq: None
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4341
Lecture: TR2-5 (E15-054)
______
No required or recommended textbooks

4.342 Introduction to Photography and Related Media
______

Graduate (Fall, Spring)
(Subject meets with4.341)
Prereq: Permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4341
Lecture: TR2-5 (E15-054)
______
Introduces history and contemporary practices in artistic photography through projects, lectures, artist visits, group discussions, readings, and field trips. Fosters visual literacy and aesthetic appreciation of photography/digital imaging, as well as critical awareness of how images in our culture are produced and constructed. Provides instruction in the fundamentals of different camera formats, film exposure and development, lighting, black and white darkroom printing, and digital imaging. Assignments allow for incorporation of a range of traditional and experimental techniques, development of technical skills, and personal exploration. Throughout the term, present and discuss projects in a critical forum. Additional work required of students taking the graduate version. Limited to 20.
L. Baladi
No required or recommended textbooks

4.344 Advanced Photography and Related Media
______

Undergrad (Fall, Spring) HASS Arts
(Subject meets with4.345)
Prereq: 4.341 or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4344
Lecture: TR EVE (7-10 PM) (E15-054)
______
Fosters critical awareness of how images in our culture are produced and constructed. Covers a range of experimental techniques and camera formats, advanced traditional and experimental black-and-white darkroom printing, and all aspects of digital imaging and output. Includes individual and group reviews, field trips, and visits from outside professionals. Topical focus changes each term; coursework centers on student-initiated project with emphasis on conceptual, theoretical, and technical development. Additional work required of students taking the graduate version. Equipment available for checkout. Limited to 20.
L. Baladi
No required or recommended textbooks

4.345 Advanced Photography and Related Media
______

Graduate (Fall, Spring) Can be repeated for credit
(Subject meets with4.344)
Prereq: 4.342 or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4344
Lecture: TR EVE (7-10 PM) (E15-054)
______
Fosters critical awareness of how images in our culture are produced and constructed. Covers a range of experimental techniques and camera formats, advanced traditional and experimental black-and-white darkroom printing, and all aspects of digital imaging and output. Includes individual and group reviews, field trips, and visits from outside professionals. Topical focus changes each term; coursework centers on student-initiated project with emphasis on conceptual, theoretical, and technical development. Additional work required of students taking the graduate version. Equipment available for checkout. Limited to 20.
L. Baladi
No required or recommended textbooks

4.352 Advanced Video and Related Media
______

Undergrad (Fall, Spring) HASS Arts
(Subject meets with4.353)
Prereq: 4.354 or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4352
Lecture: TR EVE (7-10 PM) (E15-070)
______
Introduces advanced strategies of image and sound manipulation, both technical and conceptual. Covers pre-production planning (storyboards and scripting), refinement of digital editing techniques, visual effects such as chroma-keying, post-production, as well as audio and sonic components. Context provided by regular viewings of contemporary video artworks and other audio-visual formats. Students work individually and in groups to develop skills in media literacy and communication. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff
No required or recommended textbooks

4.353 Advanced Video and Related Media
______

Graduate (Fall, Spring)
(Subject meets with4.352)
Prereq: 4.355 or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4352
Lecture: TR EVE (7-10 PM) (E15-070)
______
Introduces advanced strategies of image and sound manipulation, both technical and conceptual. Covers pre-production planning (storyboards and scripting), refinement of digital editing techniques, visual effects such as chroma-keying, post-production, as well as audio and sonic components. Context provided by regular viewings of contemporary video artworks and other audio-visual formats. Students work individually and in groups to develop skills in media literacy and communication. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff
No required or recommended textbooks

4.354 Introduction to Video and Related Media
______

Undergrad (Fall) HASS Arts
(Subject meets with4.355)
Prereq: None
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4354
Lecture: TR2-5 (E15-283A)
______
Textbooks (Fall 2016)

4.355 Introduction to Video and Related Media
______

Graduate (Fall)
(Subject meets with4.354)
Prereq: None
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4354
Lecture: TR2-5 (E15-283A)
______
Examines the technical and conceptual variables and strategies inherent in contemporary video art practice. Analyzes structural concepts of time, space, perspective, and sound within the art form. Building upon the historical legacy of film and other time-based image media, students render self-exploration, performance, social critique, and manipulation of raw experience into an aesthetic form. Emphasizes practical knowledge of lighting, video capturing and editing, and montage. Includes presentation and critique of student work, technical workshops, screenings, and readings with the objective of a final creative project. Additional work required of students taking the graduate version. Limited to 20.
C. Joskowicz
Textbooks (Fall 2016)

4.356 Cinematic Migrations
______

Undergrad (Fall) HASS Arts
(Subject meets with4.357)
Prereq: 4.301, 4.302, 4.354 or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4356
Lecture: TR2-5 (E15-070)
______
No required or recommended textbooks

4.357 Cinematic Migrations
______

Graduate (Fall) Can be repeated for credit
(Subject meets with4.356)
Prereq: 4.355 or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4356
Lecture: TR2-5 (E15-070)
______
Explores ideas and contexts behind moving images through a multifaceted look at cinema's transmutations, emergence on local and national levels, and global migrations. Examines the transformation caused by online video, television, spatial installations, performances, dance, and many formats and portable devices, as well as the theory and context of film's categorization, dissemination, and analysis. Presentations, screenings, field trips, readings, visiting artists, and experimental transdisciplinary projects broaden the perception of present cinema. Additional work required of students taking the graduate version. Limited to 12.
R. Green
No required or recommended textbooks

4.361 Performance Art Workshop
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Arts
(Subject meets with4.362)
Prereq: 4.301, 4.302, or permission of instructor
Units: 3-3-6
Subject Cancelled Subject Cancelled
______

4.362 Performance Art Workshop
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.361)
Prereq: None
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Surveys performance in relation to media and to spatial structures imagined as settings for narrative movements, and uses video to explore the perception of sounds and images and how they are altered by various devices. Students design visual forms and performative actions, and make props or objects that embody aspects of their narratives. Activities include readings and screenings on the theoretical and historical background of performance art. Assignments lead to a final performance project. Additional work required of students taking graduate version. Limited to 20.
Art, Culture and Technology Staff

4.368 Studio Seminar in Public Art/Public Sphere
______

Undergrad (Spring) HASS Arts
(Subject meets with4.369)
Prereq: 4.301, 4.302, or permission of instructor
Units: 3-3-6
______
Focuses on the production of artistic interventions in public space outside of the gallery or museum context. Explores the variety of ideas, situations, objects, and materials that shape public space. Traditional forms of commemoration are examined in comparison to temporal and critical forms of public art and action. Historical models include the Russian Constructivists, the Situationists International, conceptual art, and contemporary interventionist tactics and artistic strategies. Assigned readings and discussions help students develop an initial concept for a publicly diffused project. Additional work required of students taking graduate version. Limited to 20.
Art, Culture and Technology Staff

4.369 Studio Seminar in Public Art/Public Sphere
______

Graduate (Spring)
(Subject meets with4.368)
Prereq: None
Units: 3-3-6
______
Focuses on the production of artistic interventions in public space outside of the gallery or museum context. Explores the variety of ideas, situations, objects, and materials that shape public space. Traditional forms of commemoration are examined in comparison to temporal and critical forms of public art and action. Historical models include the Russian Constructivists, the Situationists International, conceptual art, and contemporary interventionist tactics and artistic strategies. Assigned readings and discussions help students develop an initial concept for a publicly diffused project. Additional work required of students taking graduate version. Limited to 20.
A. Muntadas

4.373 Advanced Projects in Visual Arts
______

Undergrad (Spring) HASS Arts Can be repeated for credit
(Subject meets with4.374)
Prereq: 4.301, 4.302, or permission of instructor
Units: 3-3-6
______

4.374 Advanced Projects in Visual Arts
______

Graduate (Spring) Can be repeated for credit
(Subject meets with4.373)
Prereq: Permission of instructor
Units: 3-3-6
______
Investigates conceptual and formal issues in a variety of media. Explores issues of representation, interpretation, and meaning, and how they relate to historical, social, and cultural context. Additional work required of students taking graduate version. Limited to 20.
Art, Culture and Technology Staff

4.388 Preparation for SMACT Thesis
______

Graduate (Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-6
URL: architecture.mit.edu/subject/spring-2016-4388
______
Provides assistance to students as they select a thesis topic, develop a method of approach, prepare a proposal, and develop an outline for their thesis. Explores artistic practice as method of critical inquiry. Examines artists' writing and clarifies academic requirements and standards. Regular group meetings, including peer reviews, supplemented by independent study and individual conferences with faculty. Restricted to first-year SMACT students.
Art, Culture and Technology Staff
No textbook information available

4.389 Tutorial for SMACT Thesis
______

Graduate (Spring) Can be repeated for credit
Prereq: 4.388;Coreq: 4.THG
Units: 3-0-6
URL: architecture.mit.edu/subject/spring-2016-4389
______
Includes regular presentations of students' writing in group critiques. Supports independent thesis research and thesis project by providing guidance in methodology supplemented by regular individual conferences with thesis committee members. Restricted to second-year SMACT students.
Art, Culture and Technology Staff

4.390 Art, Culture and Technology Studio
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4390
Lecture: MF2-5 (E15-001) +final
______
Explores the theory and criticism of intersections between art, culture, and technology in relation to contemporary artistic practice, critical design, and media. Students consider methods of investigation, documentation, and display and explore modes of communication across disciplines. Students develop projects in which they organize research methods and goals, engage in production, cultivate a context for their practice, and explore how to compellingly communicate, display, and document their work. Regular presentation and peer-critique sessions, as well as reviews involving ACT faculty and fellows, and external guest reviewers provide students with ample feedback as their projects develop. Restricted to SMACT students.
G. Urbonas
No required or recommended textbooks

4.391 Independent Study in Art, Culture and Technology
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.392 Independent Study in Art, Culture and Technology
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

4.393 Independent Study in Art, Culture and Technology
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.394 Independent Study in Art, Culture and Technology
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual basis. Registration subject to prior arrangement for subject matter and supervision by staff.
Art, Culture and Technology Staff
No required or recommended textbooks

4.S30 Special Subject: Art, Culture and Technology
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

4.S31 Special Subject: Art, Culture and Technology
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
______

4.S32 Special Subject: Art, Culture and Technology
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
Subject Cancelled Subject Cancelled
______

4.S33 Special Subject: Art, Culture and Technology
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: WF9.30-12.30 (E15-283A)
______
Textbooks (Fall 2016)

4.S34 Special Subject: Art, Culture and Technology
______

Graduate (Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Seminar or lecture on a topic in visual arts that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Art, Culture & Technology Staff


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Course 4: Architecture
Fall 2016


Building Technology

4.401 Environmental Technologies in Buildings
______

Undergrad (Fall)
(Subject meets with4.464)
Prereq: None
Units: 3-2-7
URL: http://architecture.mit.edu/subject/fall-2016-4401
Lecture: MW11-12.30 (1-277) Lab: F11 (1-150)
______
Introduction to the study of the thermal and luminous behavior of buildings. Examines the basic scientific principles underlying these phenomena and introduces students to a range of technologies and analysis techniques for designing comfortable indoor environments. Challenges students to apply these techniques and explore the role energy and light can play in shaping architecture. Additional work required of students taking the graduate version.
C. Reinhart
No textbook information available

4.411[J] D-Lab Schools: Building Technology Laboratory
______

Not offered academic year 2016-2017Undergrad (Fall) Institute Lab
(Same subject asEC.713[J])
Prereq: Physics I (GIR), Calculus I (GIR)
Units: 2-3-7
______
Focuses on the design, analysis, and application of technologies that support the construction of less expensive and better performing schools in developing countries. Prepares students to design or retrofit school buildings in partnership with local communities and NGOs. Strategies covered include daylighting, passive heating and cooling, improved indoor air quality via natural ventilation, appropriate material selection, and structural design. Investigations are based on application of engineering fundamentals, experiments and simulations. Case studies illustrate the role of technologies in reducing barriers to improved education.
L. K. Norford

4.42[J] Fundamentals of Energy in Buildings
______

Not offered academic year 2016-2017Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject as1.044[J],2.66[J])
Prereq: Physics I (GIR), Calculus II (GIR)
Units: 3-2-7
______
Design-based introduction to energy and thermo-sciences, with applications to sustainable, energy-efficient architecture and building technology. Covers introductory thermodynamics, air/water/vapor mixtures, and heat transfer. Studies leading order factors in building energy use. Includes several building design projects in which students creatively employ energy fundamentals and building energy use.
L. R. Glicksman

4.424[J] Modeling and Approximation of Thermal Processes
______

Graduate (Fall)
(Same subject as2.52[J])
Prereq: 2.51
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4424
Lecture: MW12.30-2 (5-217)
______
Provides instruction on how to model thermal transport processes in typical engineering systems such as those found in manufacturing, machinery, and energy technologies. Successive modules cover basic modeling tactics for particular modes of transport, including steady and unsteady heat conduction, convection, multiphase flow processes, and thermal radiation. Includes a creative design project executed by the students.
L. R. Glicksman
Textbooks (Fall 2016)

4.430 Daylighting and Solar Gain Control
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 4.464 or permission of instructor
Units arranged
______
Studies natural and electric lighting in an architectural context. Promotes the integration of occupant comfort, energy efficiency and daylight availability throughout the design process, with an emphasis on the role light can play in shaping architecture. Through group and individual projects, students practice design techniques, from rule of thumb simulations to high dynamic range photography and physical model building. Offered for 9 or 12 units.
C. Reinhart

4.431 Architectural Acoustics
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units arranged
______
Describes interactions between people and sound, indoors and outdoors, and uses this information to develop acoustical design criteria for architecture and planning. Principles of sound generation, propagation, and reception. Properties of materials for sound absorption, reflection, and transmission. Design implications for performance and gathering spaces. Use of computer modeling techniques.
Building Technology Staff

4.432 Modeling Urban Energy Flows for Sustainable Cities and Neighborhoods
______

Not offered academic year 2017-2018Undergrad (Spring)
(Subject meets with4.433)
Prereq: Permission of instructor
Units: 3-2-7
______

4.433 Modeling Urban Energy Flows for Sustainable Cities and Neighborhoods
______

Not offered academic year 2017-2018Graduate (Spring)
(Subject meets with4.432)
Prereq: Permission of instructor
Units: 3-2-4
______
Studies energy flows in and around groups of buildings from individual buildings to complete large-scale neighborhoods. Students use emerging digital techniques to analyze and influence building design interventions in relation to energy use for construction (embodied energy) and operation, access to daylight, and assessing walkability and outdoor comfort at the neighborhood scale. Additional work required of students taking the graduate version.
C. Reinhart

4.440[J] Building Structural Systems I
______

Undergrad (Spring) Rest Elec in Sci & Tech
(Same subject as1.056[J])
(Subject meets with4.462)
Prereq: Calculus II (GIR)
Units: 3-3-6
______
Introduces the design and behavior of large-scale structures and structural materials. Emphasizes the development of structural form and the principles of structural design. Presents design methods for timber, masonry, concrete and steel applied to long-span roof systems, bridges, and high-rise buildings. Includes environmental assessment of structural systems and materials. In laboratory sessions, students solve structural problems by building and testing simple models. Graduate and undergraduate students have separate lab sections.
J. Ochsendorf

4.444 Analysis of Historic Structures
______

Undergrad (Fall)
(Subject meets with1.574[J],4.445[J])
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4444
Lecture: W2-5 (1-242)
______
Textbooks (Fall 2016)

4.445[J] Analysis of Historic Structures
______

Graduate (Fall)
(Same subject as1.574[J])
(Subject meets with4.444)
Prereq: None
Units: 3-0-6
URL: http://architecture.mit.edu/subject/fall-2016-4444
Lecture: W2-5 (1-242)
______
Technical and historical study of structures in architecture and engineering. Focuses on the design and assessment of historic structures in masonry, timber, concrete, and metal. Course is driven by student research proposals. Previous student projects have researched Gothic flying buttresses, wooden covered bridges, Roman aqueducts, and iron train stations.
J. Ochsendorf
Textbooks (Fall 2016)

4.447[J] Design for Sustainability
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as1.819[J])
Prereq: Permission of instructor
Units: 2-0-4
Subject Cancelled Subject Cancelled
______
Presents thought processes and quantitative tools, including life-cycle assessment (LCA) and the LEED and ENVSION rating systems, applicable to integrated design of buildings and horizontal infrastructure with the goal of minimizing the waste of materials, energy, and water. Readings, lectures, site visits, and assignments encourage systematic thinking and interdisciplinary collaboration to make sustainable design a reality. Includes a team project of students' choice, such as a conceptual design of a sustainable new building, a "green" retrofit, or a comparative LCA.
J. Ochsendorf

4.450[J] Computational Structural Design and Optimization
______

Graduate (Fall)
(Same subject as1.575[J])
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4450
Lecture: F9-12 (9-354) +final
______
Research seminar focusing on cutting-edge applications of computation for creative, early-stage structural design and optimization for architecture. Incorporates computational design fundamentals, including problem parameterization and formulation; design space exploration strategies, including interactive, heuristic, and gradient-based optimization; and computational structural analysis methods, including the finite element method, graphic statics, and approximation techniques. Case studies introduce and investigate a range of historical and contemporary examples of structural optimization in theory and practice.
C. Mueller
No textbook information available

4.462 Building Structural Systems I
______

Graduate (Spring)
(Subject meets with1.056[J],4.440[J])
Prereq: Permission of instructor
Units: 3-2-4
URL: http://architecture.mit.edu/building-technology/subject/building-structural-systems-i
______
Introduces the design and behavior of large-scale structures and structural materials. Emphasizes the development of structural form and the principles of structural design. Introduces design methods for timber, masonry, concrete, and steel applied to long-span roof systems, bridges, and high-rise buildings. Includes environmental assessment of structural systems and materials. Laboratory to solve structural problems by building and testing simple models. Graduate and undergraduate students have separate lab sections.
J. Ochsendorf

4.463 Building Structural Systems II
______

Graduate (Fall)
Prereq: 4.440, 4.462, or permission of instructor
Units: 3-2-4
URL: http://architecture.mit.edu/subject/fall-2016-4463
Lecture: MW9.30-11 (1-150) Lab: W11-1 (5-233) +final
______
Addresses advanced structures, exterior envelopes, and contemporary production technologies. Continues the exploration of structural elements and systems, expanding to include more complex determinate, indeterminate, long-span, and high-rise systems. Topics include reinforced concrete, steel and engineered-wood design, and an introduction to tensile systems. The contemporary exterior envelope is discussed with an emphasis on the classification of systems, performance attributes, and analysis techniques, material specifications and novel construction technologies.
C. Mueller
No textbook information available

4.464 Environmental Technologies in Buildings
______

Graduate (Fall)
(Subject meets with4.401)
Prereq: None
Units: 3-2-4
URL: http://architecture.mit.edu/subject/fall-2016-4401
Lecture: MW11-12.30 (1-277) Lab: F11 (1-150) +final
______
Introduction to the study of the thermal and luminous behavior of buildings. Examines the basic scientific principles underlying these phenomena and introduces students to a range of technologies and analysis techniques for designing comfortable indoor environments. Challenges students to apply these techniques and explore the role energy and light can play in shaping architecture. Additional work required of students taking the graduate version.
C. Reinhart
No textbook information available

4.473 Design Workshop for a Sustainable Future
______

Graduate (Spring) Can be repeated for credit
Prereq: 4.151, 4.464; or permission of instructor
Units: 3-0-6
______
Focuses on strengthening the link between design and technology with an emphasis on sustainability concepts. Introduces theories behind resource-efficient built environments and how they can enhance the design process. Students explore ways to effectively integrate building performance goals, such as energy-efficiency, efficient material use, structural stability and occupant comfort into the design process. Limited to 16.
J. Ochsendorf

4.481 Building Technology Seminar
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-0-1
URL: http://architecture.mit.edu/subject/fall-2016-4481
Lecture: R3-5 (5-232)
______
Fundamental research methodologies and ongoing investigations in building tehnology to support the development of student research projects. Topics drawn from low energy building design and thermal comfort, building systems analysis and control, daylighting, structural design and analysis, novel building materials and construction techniques and resource dynamics. Organized as a series of two- and three-week sessions that consider topics through readings, discussions, design and analysis projects, and student presentations.
L. R. Glicksman, C. Mueller, J. Ochsendorf, C. Reinhart
No textbook information available

4.488 Preparation for S.M.B.T. Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4488
TBA.
______
Selection of thesis topic, definition of method of approach, and preparation of thesis proposal. Independent study supplemented by individual conference with faculty.
Building Technology Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

4.489 Preparation for Building Technology Ph.D. Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4489
TBA.
______
Selection of thesis topic, definition of method of approach, and preparation of thesis proposal. Independent study supplemented by individual conference with faculty.
Building Technology Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

4.491 Independent Study in Building Technology
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.492 Independent Study in Building Technology
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

4.493 Independent Study in Building Technology
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.494 Independent Study in Building Technology
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual basis. Registration subject to prior arrangement for subject matter and supervision by staff.
Building Technology Staff
No required or recommended textbooks

4.S40 Special Subject: Building Technology
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

4.S41 Special Subject: Building Technology
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
______

4.S42 Special Subject: Building Technology
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.S43 Special Subject: Building Technology
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.S44 Special Subject: Building Technology
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Seminar or lecture on a topic in building technology that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Building Technology Staff

4.S45 Special Subject: Building Construction
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in building construction that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Building Technology Staff

4.S46 Special Subject: Energy in Buildings
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in energy in buildings that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Building Technology Staff

4.S47 Special Subject: Architectural Lighting
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in architectural lighting that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Building Technology Staff

4.S48 Special Subject: Structural Design
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in structural design that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Architecture Building Technology Staff


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Produced: 26-SEP-2016 05:10 PMFall 2016 Course 4: Architecture
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Course 4: Architecture
Fall 2016


Computation

4.500 Introduction to Design Computing
______

Undergrad (Fall)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4500
Lecture: TR9.30-11 (4-159)
______
Introduces 3-D CAD modeling to students with little or no experience in design or computation. Teaches surface, solid and mesh modeling techniques combined with a variety of modeling applications, from 3D printing to CNC fabrication and 3D rendering. Includes weekly modeling assignments leading up to a final project. Enrollment limited; preference to Course 4 majors and minors.
L. Sass
No required or recommended textbooks

4.501 Creative Design Prototyping
______

Undergrad (Spring)
Prereq: 4.500
Units: 2-2-8
______
Introduction to digital fabrication and online presentation as a single design process. Project-based class that integrates iterative design on paper with physical prototyping across many scales. Hands on learning of fabrication lab equipment integrated with design studio. It starts with machine learning through exercises quickly moving to a stepped design to production process: 3D printings, CNC machining and robotic finishing. The final product is an individually designed and fabricated functional piece of furniture. Preference to Course 4 majors and minors.
L. Sass

4.502 Advanced Visualization: Architecture in Motion Graphics
______

Undergrad (Fall)
(Subject meets with4.562)
Prereq: 4.500 or permission of instructor
Units: 3-2-7
URL: http://architecture.mit.edu/subject/fall-2016-4502
Lab: M EVE (7 PM) (5-216) Design: M12.30-3 (4-144) +final
______
Advanced projects in architectural visualization with an emphasis on the use of computer graphics animation and video production media. Workshop introduces advanced visualization software and teaches exploration of spatial expressions in motion graphics format. Students review and discuss selected literature and video materials on architecture and film. Additional work required of students taking the graduate version. Preference to Course 4 majors and minors.
T. Nagakura
No required or recommended textbooks

4.504 Design Scripting
______

Not offered academic year 2017-2018Undergrad (Spring)
(Subject meets with4.564)
Prereq: 4.500
Units: 2-2-8
______
Introduces fundamental ideas of computer programming and demonstrates their application to the process of visual and spatial design. Teaches methods for algorithmically modeling visual and spatial forms, evaluating their conditions, building interface, and processing formal data for prototyping, manufacturing, rendering, and other design tools. Proceeds through a sequence of scripting exercises in application programming environments. Each exercise requires a student to articulate computational tasks in the context of a design, and to write codes that produce graphic solutions. Additional work required of students taking the graduate version.
T. Nagakura

4.507 Introduction to Building Information Modeling in Architecture
(New)
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with4.567)
Prereq: None
Units: 3-2-7
______
Addresses fundamental methods, theories, and practices that engage contemporary modeling tools in the context of architectural design. Introduces selected academic and professional topics through lectures, demonstrations, and assignments. Topics include parametric modeling, component types and assembly, prototyping, scripting, and simulations. Initiates intellectual explorations in the use of building information modeling in research projects and design practices. Additional work required of students taking graduate version.
T. Nagakura

4.511 Advanced Projects in Digital Fabrication
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
Independent projects in the study of digital fabrication as it relates to architecture design. Students propose a project within one of the following areas of investigation: new materials, software design for makers, fabrication based modeling, robotic fabrication.
L. Sass

4.517 Parametric and Building Information Modeling
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 4.500 or permission of instructor
Units: 3-2-7
______
Addresses professional applications of digital modeling in the development of contemporary construction systems and practical applications of geometry and digital modeling used to realize built complex forms. Surveys digitally-founded professional engineering, construction, and fabrication practices through case studies, shop visits, and on-campus and videoconference lectures. Includes modeling and making exercises, case studies, and a final project that addresses digital system design, analysis, and fabrication. Limited to 20.
Computation Staff

4.520 Visual Computing I
______

Undergrad (Spring)
(Subject meets with4.521)
Prereq: None
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduces a visual-perceptual, rule-based approach to design using shape grammars. Covers grammar fundamentals through lectures and in-class, exercises. Focuses on shape grammar applications, from stylistic analysis to creative design, through presentations of past applications and through short student exercises and projects. Presents computer programs for automating shape grammars. Additional work required of students taking graduate version.
T. Knight

4.521 Visual Computing I
______

Graduate (Spring)
(Subject meets with4.520)
Prereq: None
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Introduces a visual-perceptual, rule-based approach to design using shape grammars. Covers grammar fundamentals through lectures and in-class, exercises. Focuses on shape grammar applications, from stylistic analysis to creative design, through presentations of past applications and through short student exercises and projects. Presents computer programs for automating shape grammars. Additional work required of students taking graduate version.
T. Knight

4.522 Visual Computing II
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with4.523)
Prereq: 4.520 or permission of instructor
Units: 3-0-9
______

4.523 Visual Computing II
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.522)
Prereq: 4.520, 4.521 or permission of instructor
Units: 3-0-6
______
Introduces advanced topics in shape grammar theory and applications. Includes an introductory component on shape grammars for students new to the area. Discusses generalizations of the shape grammar formalism that provide alternative ways of computing and representing designs. These include parametric grammars and parametric design, parallel grammars, and color grammars. Presents material through lectures and in-class, applied exercises. Additional work required of graduate students.
T. Knight

4.540 Introduction to Shape Grammars I
______

Graduate (Fall)
Prereq: None
Units: 3-0-6
URL: http://architecture.mit.edu/subject/fall-2016-4540
Lecture: M9.30-12.30 (1-132)
______
No required or recommended textbooks

4.541 Introduction to Shape Grammars II
______

Graduate (Spring)
Prereq: 4.540
Units: 3-0-6
______
An in-depth introduction to shape grammars and their applications in architecture and related areas of design. Shapes in the algebras Ui j, in the algebras Vi j and Wi j incorporating labels and weights, and in algebras formed as composites of these. Rules and computations. Shape and structure. Designs.
G. Stiny

4.542 Background to Shape Grammars
______

Graduate (Spring) Can be repeated for credit
Prereq: 4.541 or permission of instructor
Units: 3-0-6
______
An advanced examination of the shape grammar formalism and its relationship to some key issues in a variety of other fields, including art and design, philosophy, history and philosophy of science, linguistics and psychology, literature and literary studies, logic and mathematics, and artificial intelligence. Student presentations and discussion of selected readings are encouraged. Topics vary from year to year. Can be repeated with permission of instructor.
G. Stiny

4.550 Computational Design Lab
______

Undergrad (Spring) Can be repeated for credit
(Subject meets with4.570)
Prereq: Permission of instructor
Units arranged
______

4.552 Workshop in Architectural Computation
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.553 Workshop in Architectural Computation
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Opportunity for exploration of a topic in computation through research-focused design projects or exercises. Registration subject to prior arrangement of topic and supervision by staff.
Computation Staff

4.557[J] City Science
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject asMAS.552[J])
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4557
Lecture: W2-5 (E15-359)
______
Focuses on architectural and mobility interventions that respond to changing patterns of living, working, and transport. Emphasizes mass-customized housing, autonomous parking, charging infrastructure, and shared-use networks of lightweight electric vehicles (LEVs). Students work in small teams and are lead by researchers from the Changing Places group. Projects focus on the application of these ideas to case study cities and may include travel. Invited guests from academia and industry participate. Repeatable for credit with permission of instructor.
K. Larson, R. Chin
No textbook information available

4.562 Advanced Visualization: Architecture in Motion Graphics
______

Graduate (Fall)
(Subject meets with4.502)
Prereq: Permission of instructor
Units: 3-2-7
URL: http://architecture.mit.edu/subject/fall-2016-4502
Lab: M EVE (7 PM) (5-216) Design: M12.30-3 (4-144) +final
______
Advanced projects in architectural visualization with an emphasis on the use of computer graphics animation and video production media. Introduces advanced visualization software and teaches exploration of spatial expressions in motion graphics format. Students review and discuss selected literature and video materials on architecture and film. Additional work required of students taking the graduate version.
T. Nagakura
No required or recommended textbooks

4.564 Design Scripting
______

Not offered academic year 2017-2018Graduate (Spring)
(Subject meets with4.504)
Prereq: Permission of instructor
Units: 2-2-8
______
Introduces fundamental ideas of computer programming and demonstrates their application to the process of visual and spatial design. Teaches methods for algorithmically modeling visual and spatial forms, evaluating their conditions, building interface, and processing formal data for prototyping, manufacturing, rendering, and other design tools. Proceeds through a sequence of scripting exercises in application programming environments. Each exercise requires a student to articulate computational tasks in the context of a design, and to write codes that produce graphic solutions. Additional work required of students taking the graduate version.
T. Nagakura

4.566 Advanced Projects in Digital Media
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 4.562, 4.564, or permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4566
Lecture: W EVE (5-7 PM) (7-304)
______
Develop independent projects in the study of digital media as it relates to architectural design. Students propose a project topic such as digital design tool, modeling and visualization, motion graphics, design knowledge representation and media interface.
T. Nagakura
No required or recommended textbooks

4.567 Introduction to Building Information Modeling in Architecture
(4.561)
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.507)
Prereq: None
Units: 3-2-7
______
Addresses fundamental methods, theories, and practices that engage contemporary modeling tools in the context of architectural design. Introduces selected academic and professional topics through lectures, demonstrations, and assignments. Topics include parametric modeling, component types and assembly, prototyping, scripting, and simulations. Initiates intellectual explorations in the use of building information modeling in research projects and design practices. Additional work required of students taking graduate version.
T. Nagakura

4.569[J] Designing Interactions
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject asCMS.834[J])
(Subject meets withCMS.634)
Prereq: None
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4569
Lecture: W10-1 (E15-335)
______
Explores the future of mobile interactions and pervasive computing, taking into consideration design, technological, social and business aspects. Discusses theoretical works on human-computer interaction, mobile media and interaction design, and covers research and design methods. Students work in multidisciplinary teams and participate in user-centric design projects aimed to study, imagine and prototype concepts illustrating the future of mobile applications and ubiquitous computing. Students taking graduate version complete additional assignments. Repeatable for credit with permission of instructor. Limited to 12.
F. Casalegno, T. Nagakura
No textbook information available

4.570 Computational Design Lab
______

Graduate (Spring) Can be repeated for credit
(Subject meets with4.550)
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/spring-2014-4570
______
Provides students with an opportunity to explore projects that engage real world problems concerning spatial design, technology, media, and society. In collaboration with industry partners and public institutions, students identify topical issues and problems, and also explore and propose solutions through the development of new ideas, theories, tools, and prototypes. Industry and academic collaborators act as a source of expertise, and as clients and critics of projects developed during the term. General theme of workshop varies by semester or year. Open to students from diverse backgrounds in architecture and other design-related areas. Additional work required of students taking graduate version.
Computation Staff

4.580 Inquiry into Computation and Design
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4580
Lecture: T9.30-12.30 (9-450A)
______
Explores the varied nature, history and practice of computation in design through lectures, readings, small projects, discussions, and guest visits by Computation group faculty and others. Topics may vary from year to year. Aims to help students develop a critical awareness of different approaches to and assumptions about computation in design beyond the specifics of techniques and tools, and to open avenues for further research.
T. Knight
No required or recommended textbooks

4.581 Proseminar in Computation
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9 [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4581
Lecture: T9.30-12.30 (5-232)
______
Introduction to traditions of research in design and computation scholarship.
G. Stiny
No required or recommended textbooks

4.582 Research Seminar in Computation
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 4.580 or permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4581
TBA.
______
In-depth presentations of current research in design and computation.
G. Stiny
No required or recommended textbooks

4.583 Forum in Computation
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of Instructor
Units: 3-0-0 [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4583
Lecture: W EVE (6-8 PM) (5-216)
______
Group discussions and presentation of ongoing graduate student research in the Computation program.
T. Knight
No textbook information available

4.584 Reading Seminar in Design and Computation
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4584
Subject Cancelled Subject Cancelled
______
Reading and discussion of particular topics in design and computation. Students lead discussions, make oral presentations, and prepare reviews of weekly readings.
T. Knight

4.587 SMArchS Computation Pre-Thesis Preparation
______

Graduate (Spring)
Prereq: 4.221 or permission of instructor
Units: 3-0-3 [P/D/F]
URL: architecture.mit.edu/subject/spring-2016-4587
______
Preliminary study in preparation for the thesis for the SMArchS degree in Computation. Topics include literature search, precedents examination, thesis structure and typologies, and short writing exercise.
T. Knight, T. Nagakura

4.589 Preparation for Design and Computation PhD Thesis
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4589
TBA.
______
Selection of thesis topic, definition of method of approach, and preparation of thesis proposal in computation. Independent study supplemented by individual conference with faculty.
Computation Staff
No textbook information available

4.591 Independent Study in Architectural Computation
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.592 Independent Study in Architectural Computation
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

4.593 Independent Study in Architectural Computation
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.594 Independent Study in Architectural Computation
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual basis. Registration subject to prior arrangement for subject matter and supervision by staff.
Computation Staff
No required or recommended textbooks

4.S50 Special Subject: Architectural Computation
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

4.S51 Special Subject: Architectural Computation
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
______

4.S52 Special Subject: Architectural Computation
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: R EVE (5-8 PM) (4-144)
______
No textbook information available

4.S53 Special Subject: Architectural Computation
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.S54 Special Subject: Architectural Computation
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Seminar or lecture on a topic in computation and design that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Computation Staff

4.S55 Special Subject: Digital Fabrication
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in computation and design that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
L. Sass, D. Smithwick

4.S56 Special Subject: Shape Grammars
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in computation and design that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Computation Staff


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Produced: 26-SEP-2016 05:10 PMFall 2016 Course 4: Architecture
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Course 4: Architecture
Fall 2016


History, Theory and Criticism of Architecture and Art

4.601 Introduction to Art History
______

Undergrad (Fall) HASS Arts
Prereq: None
Units: 3-2-7
URL: http://architecture.mit.edu/subject/fall-2016-4601
Lecture: TR2-3.30 (3-133) Recitation: W1 (5-216) or F1 (5-216) +final
______
Introduction to the history and interpretation of western art that explores painting, graphic arts and sculpture from the Renaissance to the present. Engages diverse methodological perspectives to examine changing conceptions of art and the artist, and to investigate the plural meaning of artworks within the larger contexts of culture and history. Subject includes trips to local museums.
D. Pullins
Textbooks (Fall 2016)

4.602 Modern Art and Mass Culture
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Arts Communication Intensive HASS
(Subject meets with4.652)
Prereq: None
Units: 4-0-8
______
Introduction to theories of modernism and postmodernism and their related forms (roughly 18th century to present) in art and design. Focuses on how artists use the tension between fine art and mass culture to critique both. Examines visual art in a range of genres, from painting to design objects and "relational aesthetics." Works of art are viewed in their interaction with advertising, caricature, comics, graffiti, television, fashion, "primitive" art, propaganda, and networks on the internet. Additional work required of students taking graduate version.
C. Jones

4.603 Understanding Modern Architecture
______

Undergrad (Fall) HASS Arts
(Subject meets with4.604)
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4603
Lecture: MW9.30-11 (4-153)
______
Examines modern architecture, art, and design in the context of the political, economic, aesthetic, and cultural changes that occurred in the twentieth century. Presents foundational debates about social and technological aspects of modern architecture and the continuation of those debates into contemporary architecture. Incorporates varied techniques of historical and theoretical analysis to interpret exemplary objects, buildings, and cities of modernity. Additional work required of students taking the graduate version. Preference to Course 4 majors and minors.
T. Hyde
Textbooks (Fall 2016)

4.604 Understanding Modern Architecture
______

Graduate (Fall)
(Subject meets with4.603)
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4603
Lecture: MW9.30-11 (4-153)
______
Examines modern architecture, art, and design in the context of the political, economic, aesthetic, and cultural changes that occurred in the twentieth century. Presents foundational debates about social and technological aspects of modern architecture and the continuation of those debates into contemporary architecture. Incorporates varied techniques of historical and theoretical analysis to interpret exemplary objects, buildings, and cities of modernity. Additional work required of students taking the graduate version. Preference to Course 4 majors.
T. Hyde
Textbooks (Fall 2016)

4.605 A Global History of Architecture
______

Undergrad (Spring) HASS Arts
(Subject meets with4.650)
Prereq: None
Units: 4-0-8
______
Provides an outline of the history of architecture and urbanism from ancient times to the early modern period. Analyzes buildings as the products of culture and in relation to the special problems of architectural design. Stresses the geopolitical context of buildings and in the process familiarizes students with buildings, sites and cities from around the world. Additional work required of graduate students.
M. Jarzombek

4.606 Visual Perception and Art
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Arts Communication Intensive HASS
Prereq: None
Units: 3-2-7
______
Introduces visual perception from neurological, cultural, and artistic vantage points. Examines aspects of visual culture ranging from body adornment to public spaces, and from logotypes to moving images. Topics range from ritual space to forensics to machine-aided vision (cameras, radar devices, robotic scanners). Designed to develop skills in visual analysis and interpretation through lectures, oral presentations, field trips, and written essays. Enrollment limited.
C. Jones

4.607 Thinking About Architecture: In History and At Present
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 4.645 or permission of instructor
Units arranged
______
Studies the interrelationship of theory, history, and practice. Looks at theory not as specialized discourse relating only to architecture, but as touching on many issues, whether they be cultural, aesthetic, philosophical, or professional. Topics and examples are chosen from a wide range of materials, from classical antiquity to today.
M. Jarzombek

4.608 Seminar in the History of Art and Architecture
______

Graduate (Spring)
(Subject meets with4.609)
Prereq: Permission of instructor
Units arranged
______
Examination of historical method in art and/or architecture, focusing on periods and problems determined by the research interest of the faculty member leading the seminar. Emphasizes critical reading and viewing and direct tutorial guidance. Additional work required of students taking the graduate version.
HTC Staff

4.609 Seminar in the History of Art and Architecture
______

Undergrad (Spring) HASS Arts
(Subject meets with4.608)
Prereq: Permission of instructor
Units: 3-0-9
______
Examination of historical method in art and/or architecture, focusing on periods and problems determined by the research interest of the faculty member leading the seminar. Emphasizes critical reading and viewing and direct tutorial guidance. Additional work required of students taking the graduate version.
HTC Staff

4.610 Civic Islamic Architecture
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Arts
(Subject meets with4.611)
Prereq: None
Units: 3-0-9
______

4.611 Civic Islamic Architecture
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.610)
Prereq: None
Units arranged
______
In-depth analysis of selected examples of architecture in the Islamic world from the 7th to the 21st century. Examines the effects of politics, culture, religion, technology, and fashion on the formation and development of Islamic architectural traditions and situates them diachronically and synchronically in world context. Additional work required of students taking the graduate version.
N. Rabbat

4.612 Islamic Architecture and the Environment
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
URL: http://architecture.mit.edu/subject/fall-2016-4612
Lecture: M2-5 (5-216) +final
______
Studies how Islamic architecture, landscape architecture, and urban planning reflect and transform environmental processes in various regions and climates of the Islamic world, from Andalusia to Southeast Asia, with an emphasis on South Asia, Central Asia, and the Middle East. Using systematic approaches to environmental data collection and analysis, examines strategies behind the design of selected architectural elements and landscape design types, ranging in scale from the fountain to the garden, courtyard, city, and agrarian region. Critically explores cultural interpretations of Islamic environmental design (e.g., paradise gardens), as they developed over time in ways that enrich, modify, or obscure their historical significance.
J. Wescoat
No textbook information available

4.614 Architecture in the Islamic World
______

Undergrad (Fall) HASS Arts
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4614
Lecture: TR11-12.30 (5-216)
______
Introduces the history of Islamic cultures that spans fourteen centuries and three continents - Asia, Africa, Europe - and recent developments in the United States. Studies a number of representative examples, from the House of the Prophet to the present, in conjunction with their urban, social, political, and intellectual environments. Presents Islamic architecture both as a full-fledged historical tradition and as a dynamic and interactive cultural catalyst that influenced and was influenced by the civilizations with which it came in contact.
N. Rabbat
Textbooks (Fall 2016)

4.616 Selected Topics on Culture and Architecture
______

Graduate (Spring)
Prereq: Permission of instructor
Units arranged
______
Seminar on how culture interacts with architecture. Analyzes architecture as a conveyor of messages that transcend stylistic, formal, and iconographic concerns to include an assessment of disciplinary, political, ideological, social, and cultural factors. Critically reviews methodologies and theoretical premises of studies on culture and meaning. Focuses on examples from Islamic history and establishes historical and theoretical frameworks for investigation.
N. Rabbat

4.617 Issues in Islamic Urbanism
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units arranged
______
Seminar on selected topics from the history of Islamic urbanism. Examines patterns of settlement, urbanization, development, and architectural production in various places and periods, ranging from the formative period in the 7th century to the new cities emerging today. Discusses the leading factors in shaping and transforming urban forms, design imperatives, cultural and economic structures, and social and civic attitudes. Critically analyzes the body of literature on Islamic urbanism. Research paper required.
N. Rabbat

4.619 Historiography of Islamic Architecture
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4619
Lecture: W2-5 (5-216)
______
Critical review of literature on Islamic art and architecture in the last two centuries. Analyzes the cultural, disciplinary, and theoretical contours of the field and highlights the major figures that have influenced its evolution. Challenges the tacit assumptions and biases of standard studies of Islamic art and architecture and addresses historiographic and critical questions concerning how knowledge of a field is defined, produced, and reproduced.
N. Rabbat
No textbook information available

4.621 Orientalism and Representation
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units arranged
______
Seminar on the politics of representation with special focus on Orientalist traditions in architecture, art, literature, and scholarship. Critically analyzes pivotal texts, projects, and artworks that reflected the encounters between the West and the Orient from Antiquity to the present. Discusses how political, ideological, and religious attitudes informed the construction and reproduction of Western knowledge about the Islamic world as well as revisionist Eastern self-representations. Research paper required.
N. Rabbat

4.622 Islamic Gardens and Geographies
(New)
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with4.623)
Prereq: Permission of Instructor
Units: 3-0-9
______
Seminar focuses on the historical geography of Islamic gardens, from Andalusia to Southeast Asia, with an emphasis on the Indian subcontinent. Critically engages evidence from archaeological, art historical, and cartographic sources, and explores strategies for generating integrative accounts of historical landscapes. Topics include gardens, cities, cultural landscapes, and political territories, along with their contemporary significance for cultural heritage conservation and design. Additional work required of graduate students. Limited to 15.
J. Wescoat

4.623 Islamic Gardens and Geographies
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.622)
Prereq: Permission of instructor
Units: 3-0-9
______
Seminar focuses on the historical geography of Islamic gardens, from Andalusia to Southeast Asia, with an emphasis on the Indian subcontinent. Critically engages evidence from archaeological, art historical, and cartographic sources, and explores strategies for generating integrative accounts of historical landscapes. Topics include gardens, cities, cultural landscapes, and political territories, along with their contemporary significance for cultural heritage conservation and design. Additional work required of graduate students. Limited to 15.
J. Wescoat

4.625[J] Water Planning, Policy, and Design
______

Graduate (Fall) Can be repeated for credit
(Same subject as11.378[J])
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4625
Lecture: T9-12 (1-375) +final
______
Focuses on water in environmental planning, policy, and design. Draws together faculty and students who are working on water-related research projects to develop and maintain a current perspective on the field from the site to metropolitan and international scales. Limited to 15.
J. Wescoat
No textbook information available

4.633 Locating Capitalism: Producing Early Modern Cities and Objects
______

Graduate (Spring)
Prereq: Permission of instructor
Units arranged
______
Explores what defines the parameters of an early modern profit economy in Europe. Discusses major interpretive frameworks that historically have guided scholarship on the period in architectural, art, and economic history. Traces the core themes of commodification, production, and consumption - analyzing the relevance of studies on pre- and early modern globalization - to the culture and time under consideration. Can be taken for 9 or 12 units.
L. Jacobi

4.634 Early Modern Architecture and Art
______

Graduate (Fall)
(Subject meets with4.635)
Prereq: None
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4634
Lecture: TR11-12.30 (3-133) +final
______
No textbook information available

4.635 Early Modern Architecture and Art
______

Undergrad (Fall) HASS Arts
(Subject meets with4.634)
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4634
Lecture: TR11-12.30 (3-133) +final
______
Presents a history, from the 14th through the early 17th century, of architectural practice and design, as well as visual culture in Europe with an emphasis on Italy. Topics include the production and reception of buildings and artworks; the significance of a reinvigorated interest in antiquity; and representation of the individual, the state, and other institutions.Examines a variety of interpretive methods. Graduate students are expected to complete additional assignments.
L. Jacobi
No required or recommended textbooks

4.640 Advanced Study in Critical Theory of Architecture
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4640
Lecture: T2-5 (5-216)
______
Seminar on a selected topic in critical theory. Requires original research and presentation of oral and written report.
L. Jacobi
No textbook information available

4.641 19th-Century Art
______

Undergrad (Spring) HASS Arts
(Subject meets with4.644)
Prereq: None
Units: 4-0-8
______

4.644 19th-Century Art
______

Graduate (Spring)
(Subject meets with4.641)
Prereq: None
Units arranged
______
Survey of visual culture from the late 18th century to 1900 with an emphasis on Western Europe and its global points of contact. Topics include art and revolution, empire and its image, mythologies of the artist, gender and representation, public exhibitions, the dealer/critic system, and the emergence of the avant-garde. Strikes a balance between historical and contemporary critical perspectives to assess art's engagement with social and political experience of modernity. Additional work required of students taking the graduate version.
K. Smentek

4.645 Selected Topics in Architecture: 1750 to the Present
______

Graduate (Spring)
Prereq: 4.210 or permission of instructor
Units: 3-0-6
______
General study of modern architecture as a response to important technological, cultural, environmental, aesthetic, and theoretical challenges after the European Enlightenment. Focus on the theoretical, historiographic, and design approaches to architectural problems encountered in the age of industrial and post-industrial expansion across the globe, with specific attention to the dominance of European modernism in setting the agenda for the discourse of a global modernity at large. Explores modern architectural history through thematic exposition rather than as simple chronological succession of ideas.
A. Dutta

4.646 Advanced Study in the History of Modern Architecture and Urbanism
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
______
Seminar in a selected topic in the history of modern architecture and urbanism. Oral presentations and research paper required.
T. Hyde

4.647 Technopolitics, Culture, Intervention
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 4.645 or permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4647
Lecture: W2-5 (1-371)
______
Examines the manner in which key theories of technology have influenced architectural and art production in terms of their "humanizing" claims. Students test theories of technology on the grounds of whether technology is good or bad for humans. Limited to 15; preference to MArch students.
A. Dutta
No required or recommended textbooks

4.648[J] Resonance: Sonic Experience, Science, and Art
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Arts
(Same subject as21A.507[J])
(Subject meets with4.649[J],21A.519[J])
Prereq: None
Units: 3-0-9
______
Examines the sonic phenomena and experiences that motivate scientific, humanistic, and artistic practices. Explores the aesthetic and technical aspects of how we hear; measure or describe vibrations; record, compress, and distribute resonating materials; and how we ascertain what we know about the world through sound. Although the focus is on sound as an aesthetic, social, and scientific object, the subject also investigates how resonance is used in the analysis of acoustics, architecture, and music theory. Students make a sonic artifact or research project as a final requirement. Students taking graduate version complete additional assignments.
S. Helmreich, C. Jones

4.649[J] Resonance: Sonic Experience, Science, and Art
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as21A.519[J])
(Subject meets with4.648[J],21A.507[J])
Prereq: None
Units: 3-0-9
______
Examines the sonic phenomena and experiences that motivate scientific, humanistic, and artistic practices. Explores the aesthetic and technical aspects of how we hear; measure or describe vibrations; record, compress, and distribute resonating materials; and how we ascertain what we know about the world through sound. Although the focus is on sound as an aesthetic, social, and scientific object, the subject also investigates how resonance is used in the analysis of acoustics, architecture, and music theory. Students make a sonic artifact or research project as a final requirement. Students taking graduate version complete additional assignments.
S. Helmreich, C. Jones

4.650 A Global History of Architecture
(New)
______

Graduate (Spring)
(Subject meets with4.605)
Prereq: None
Units: 4-0-8
______
Provides an outline of the history of architecture and urbanism from ancient times to the early modern period. Analyzes buildings as the products of culture and in relation to the special problems of architectural design. Stresses the geopolitical context of buildings and in the process familiarizes students with buildings, sites and cities from around the world. Additional work required of graduate students.
M. Jarzombek

4.651 Art Since 1940
______

Undergrad (Spring) HASS Arts
Prereq: None
Units: 3-0-9
______
Critical examination of major developments in European, Asian, and American art from 1940 to the present. Surveys the mainstream of art production but also examines marginal phenomena (feminism, identity politics, AIDS activism, net art) that come to change the terms of arts engagements with civic culture. Visits to area art museums and writing assignments develop skills for visual analysis and critical writing.
C. Jones

4.652 Modern Art and Mass Culture
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.602)
Prereq: None
Units arranged
______
Introduction to theories of modernism and postmodernism and their related forms (roughly 18th century to present) in art and design. Focuses on how artists use the tension between fine art and mass culture to critique both. Examines visual art in a range of genres, from painting to design objects and "relational aesthetics." Works of art are viewed in their interaction with advertising, caricature, comics, graffiti, television, fashion, "primitive" art, propaganda, and networks on the internet. Additional work required of students taking the graduate version.
C. Jones

4.657 Design: The History of Making Things
(New)
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: None
Units: 5-0-7
______
Examines themes in the history of design, with emphasis on Euro-American theory and practice in their global contexts. Addresses the historical design of communications, objects, and environments as meaningful processes of decision-making, adaptation, and innovation. Critically assesses the dynamic interaction of design with politics, economics, technology, and culture in the past and at present.
T. Hyde, K. Smentek

4.661 Theory and Method in the Study of Architecture and Art
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4661
Lecture: M11-2 (5-216)
______
Studies theoretical and historiographical works pertaining to the fields of art and architectural history. Members of seminar pursue work designed to examine their own presuppositions and methods. Open only to PhD candidates and other advanced students.
M. Jarzombek
No required or recommended textbooks

4.670 Nationalism, Internationalism, and Globalism in Modern Art
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.671)
Prereq: None
Units arranged
4.670: URL: http://architecture.mit.edu/subject/spring-2016-4670
______

4.671 Nationalism, Internationalism, and Globalism in Modern Art
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with4.670)
Prereq: 4.601 or permission of instructor
Units: 3-1-8
URL: http://architecture.mit.edu/subject/spring-2016-4670
______
Studies how international modernism interacted with the concept of "nation" and how contemporary discourses concerning globalism changes that dynamic. Looks at how art uses and critiques globalization on various levels. Seminar attendance and visits to art museums required. Research paper required of students taking the graduate version.
C. Jones

4.672 Installation Art
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with4.673)
Prereq: None
Units arranged
______

4.673 Installation Art
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with4.672)
Prereq: 4.601 or permission of instructor
Units: 3-0-9
______
Focuses on a specific genre of contemporary art that produces environments or room-sized immersive forms rather than portable "art objects." Installation art is viewed from a historical perspective, as a rejection of the modernist aesthetic of purity and the neutral white gallery space. Its corollary in site-specific art is explored in relation to previous exhibition models such as natural history displays or merchandising conventions. Graduate students will be expected to produce a final research paper.
C. Jones

4.675 Collect, Classify, Consume
______

Graduate (Spring) Can be repeated for credit
Prereq: None
Units arranged
______
Historical study of collecting from the Renaissance to the present. Addresses the practices of collecting and display at the both the individual and institutional level, and analyzes their social, aesthetic, scientific, political and economic dimensions. Specific themes vary from year to year. Offered for 9 or 12 units. May be repeated for credit with permission of instructor.
K. Smentek

4.677 Advanced Study in the History of Art
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
______
Seminar in a selected topic in the history of art, with a particular emphasis on developments from the 18th century to the present. Oral presentations and research paper required. Offered for 9 or 12 units.
K. Smentek

4.683 Preparation for HTC Qualifying Paper
(New)
______

Graduate (Fall, Spring)
Prereq: Permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4683
TBA.
______
Required of doctoral students in HTC as a prerequisite for work on the doctoral dissertation. The qualifying paper is a scholarly article fit to be published in a peer-reviewed journal that is the result of research in the history, theory and criticism of architecture and art. Topic may not be in the area of the proposed thesis. Work is done in consultation with HTC faculty, in accordance with the HTC PhD Degree Program Guidelines. Restricted to HTC PhD students.
HTC Staff
No textbook information available

4.684 Preparation for HTC Major Exam
(New)
______

Graduate (Fall, Spring)
Prereq: permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4684
TBA.
______
Required of doctoral students in HTC as a prerequisite for work on the doctoral dissertation. The Major Exam covers a historically broad area of interest and includes components of history, historiography, and theory. Preparation for the exam will focus on four or five themes agreed upon in advance by the student and the examiner, and are defined by their area of teaching interest. Work is done in consultation with HTC faculty, in accordance with the HTC PhD Degree Program Guidelines. Restricted to HTC PhD students.
HTC Staff
No textbook information available

4.685 Preparation for HTC Minor Exam
(New)
______

Graduate (Fall, Spring)
Prereq: permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4685
TBA.
______
Required of doctoral students in HTC as a prerequisite for work on the doctoral dissertation. The Minor Exam focuses on a specific area of specialization through which the student might develop their particular zone of expertise. Work is done in consultation with HTC faculty, in accordance with the HTC PhD Degree Program Guidelines. Restricted to HTC PhD students.
HTC Staff
No textbook information available

4.686 SMArchS AKPIA Pre-Thesis Preparation
______

Graduate (Fall, Spring)
Prereq: 4.221; 4.619 or 4.621
Units: 0-1-2 [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4686
TBA.
______
Preliminary study in preparation for the thesis for the SMArchS degree in the Aga Khan Program for Islamic Architecture. Topics include literature search, precedents examination, thesis structure and typologies, and short writing exercise.
N. Rabbat, J. Wescoat
No required or recommended textbooks

4.687 SMArchS HTC Pre-Thesis Preparation
______

Graduate (Fall, Spring)
Prereq: 4.221, 4.661
Units: 0-1-2 [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4687
TBA.
______
Preliminary study in preparation for the thesis for the SMArchS degree in History, Theory and Criticism. Topics include literature search, precedents examination, thesis structure and typologies, and short writing exercise.
HTC Staff
No required or recommended textbooks

4.689 Preparation for History, Theory, and Criticism - Ph.D. Thesis
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4689
TBA.
______
Required for doctoral students in HTC as a prerequisite for work on the doctoral dissertation. Prior to candidacy, doctoral students are required to write and orally defend a proposal laying out the scope of their thesis, its significance, a survey of existing research and literature, the methods of research to be adopted, a bibliography and plan of work. Work is done in consultation with HTC Faculty, in accordance with the HTC PhD Degree Program guidelines. Restricted to HTC PhD students.
HTC Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

4.691 Independent Study in the History, Theory, and Criticism of Architecture and Art
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Supplementary work on individual or group basis. Registration subject to prior arrangement for subject matter and supervision by staff.
HTC Staff
No required or recommended textbooks

4.692 Independent Study in the History, Theory, and Criticism of Architecture and Art
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual or group basis. Registration subject to prior arrangement for subject matter and supervision by staff.
HTC Staff
No required or recommended textbooks

4.693 Independent Study in the History, Theory, and Criticism of Architecture and Art
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Supplementary work on individual basis. Registration subject to prior arrangement for subject matter and supervision by staff.
HTC Staff
No required or recommended textbooks

4.694 Independent Study in the History, Theory, and Criticism of Architecture and Art
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual basis. Registration subject to prior arrangement for subject matter and supervision by staff.
HTC Staff
No required or recommended textbooks

4.S60 Special Subject: History, Theory and Criticism of Architecture and Art
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______
Seminar or lecture on a topic in the history, theory and criticism of architecture and art that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
HTC Staff

4.S61 Special Subject: History, Theory and Criticism of Architecture and Art
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
______
Seminar or lecture on a topic in the history, theory and criticism of architecture and art that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
HTC Staff

4.S62 Special Subject: History, Theory and Criticism of Architecture and Art
______

Graduate (Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in the history, theory and criticism of architecture and art that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
HTC Staff

4.S63 Special Subject: History, Theory and Criticism of Architecture and Art
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in the history, theory and criticism of architecture and art that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
HTC Staff

4.S64 Special Subject: History, Theory and Criticism of Architecture and Art
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Seminar or lecture on a topic in the history, theory and criticism of architecture and art that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
HTC Staff

4.S65 Special Subject: Advanced Study in Islamic Architecture
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in Islamic or non-western architecture that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports, varying at the discretion of the instructor.
HTC Staff

4.S66 Special Subject: History, Theory and Criticism of Art
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in the history, theory and criticism of art that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
HTC Staff

4.S67 Special Subject: Study in Modern Art
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: F10-1 (5-216)
______
Seminar or lecture on a topic in the history, theory and criticism of modern art that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
C. Jones, R. Uchill
No required or recommended textbooks

4.S68 Special Subject: Study in Modern Architecture
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4s68
Lecture: W9.30-12.30 (5-216)
______
Seminar or lecture on a topic in the history, theory and criticism of modern architecture that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
M. Jarzombek
No textbook information available

4.S69 Special Subject: Advanced Study in the History of Urban Form
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in the history, theory and criticism of urban form that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
HTC Staff


left arrow|Architecture Design|Architecture Studies|Art, Culture and Technology|Building Technology|Computation|History, Theory and Criticism of Architecture and Art|Thesis and UROP|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 4: Architecture
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Course 4: Architecture
Fall 2016


Thesis and UROP


Graduate Subjects

Preparatory subjects for thesis are listed within each of the disciplinary headings of the subject listing.

4.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research and writing of thesis; to be arranged by the student with supervising committee.
Staff
Textbooks arranged individually


Undergraduate Subjects

4.119 Preparation for Undergraduate Architecture Design Thesis
______

Undergrad (Fall)
Prereq: 4.024
Units: 2-0-10
URL: http://architecture.mit.edu/subject/fall-2016-4119
Lecture: F10
______
Selection of thesis topic, defining method of approach, and preparation of thesis proposal for BSA degree in architecture. Weekly class meeting as well as individual conference with faculty.
J. Lamere
No textbook information available

4.THT[J] Thesis Research Design Seminar
______

Undergrad (Fall) Can be repeated for credit
(Same subject as11.THT[J])
Prereq: None
Units: 3-0-9
Lecture: F12-3 (9-217)
______
Designed for students writing a thesis in Urban Studies and Planning or Architecture. Develop research topics, review relevant research and scholarship, frame research questions and arguments, choose an appropriate methodology for analysis, and draft introductory and methodology sections.
C. Abbanat
No required or recommended textbooks

4.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 4.THT or 4.119
Units arranged
TBA.
______
Program of thesis research leading to the writing of an SB thesis, to be arranged by the student and an appropriate MIT faculty member. Intended for seniors. 12 units recommended.
Architecture Staff
Textbooks arranged individually

4.UR Undergraduate Research in Design
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually

4.URG Undergraduate Research in Design
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Research and project activities, which cover the range represented by the various research interests and projects in the department. Students who wish a letter grade option for their work must register for 4.URG.
L. Sass
Textbooks arranged individually


left arrow|Architecture Design|Architecture Studies|Art, Culture and Technology|Building Technology|Computation|History, Theory and Criticism of Architecture and Art|Thesis and UROP|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 5: Chemistry
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Course 5: Chemistry
Fall 2016


5.00[J] Energy Technology and Policy: From Principles to Practice
______

Graduate (Spring)
(Same subject as6.929[J],10.579[J],22.813[J])
Prereq: None
Units: 3-0-6
______
Develops analytical skills to lead a successful technology implementation with an integrated approach that combines technical, economical and social perspectives. Considers corporate and government viewpoints as well as international aspects, such as nuclear weapons proliferation and global climate issues. Discusses technologies such as oil and gas, nuclear, solar, and energy efficiency. Limited to 100.
J. Deutch

5.03 Principles of Inorganic Chemistry I
______

Undergrad (Spring)
Prereq: 5.12
Units: 5-0-7
______
Presents principles of chemical bonding and molecular structure, and their application to the chemistry of representative elements of the periodic system.
A. Radosevich, Y. Surendranath

5.04 Principles of Inorganic Chemistry II
______

Undergrad (Fall)
Prereq: 5.03
Units: 4-0-8
Lecture: MWF9 (2-105) Recitation: F12 (8-205) or F1 (8-205)
______
Systematic presentation of the chemical applications of group theory. Emphasis on the formal development of the subject and its applications to the physical methods of inorganic chemical compounds. Against the backdrop of electronic structure, the electronic, vibrational, and magnetic properties of transition metal complexes are presented and their investigation by the appropriate spectroscopy described.
M. Dinca, Y. Surendranath
Textbooks (Fall 2016)

5.05 Principles of Inorganic Chemistry III
______

Graduate (Fall)
Prereq: 5.03,Coreq: 5.04
Units: 2-0-4
Lecture: TR8.30-10 (8-205)
______
Principles of main group (s and p block) element chemistry with an emphasis on synthesis, structure, bonding, and reaction mechanisms.
C. C. Cummins
No textbook information available

5.061 Principles of Organometallic Chemistry
______

Graduate (Spring); first half of term
Prereq: 5.03
Units: 2-0-4
______
A comprehensive treatment of organometallic compounds of the transition metals with emphasis on structure, bonding, synthesis, and mechanism.
R. Schrock

5.062 Principles of Bioinorganic Chemistry
______

Graduate (Fall)
Prereq: 5.03
Units: 3-0-9
Lecture: TR10-11.30 (2-105)
______
Delineates principles that form the basis for understanding how metal ions function in biology. Includes the choice, uptake and assembly of metal-containing units; metal-induced folding of biomolecules; control of metal ion concentrations in cells; electron-transfer chemistry; atom and group transfer chemistry; protein tuning of metal properties; and applications to diagnosis and treatment of disease. Introduces additional topics to expose students to exciting new advances in the field, such as medicinal application of inorganic chemistry; multi-component enzyme systems (e.g.,nitrogenase, hydrogenase, and photosystem II); and metalloprotein engineering and design (e.g., the conversion by mutagenesis of existing metalloprotein scaffolds to achieve novel functions).
S. Lippard
Textbooks (Fall 2016)

5.063 Organometallic Compounds in Catalytic Reactions
______

Not offered academic year 2017-2018Graduate (Spring); first half of term
Prereq: 5.061
Units: 2-0-4
______
An exploration of organometallic chemistry from the perspective of catalytic reactions in organic and polymer chemistry.
R. Schrock

5.067 Crystal Structure Refinement
______

Graduate (Fall)
Prereq: 5.068, 5.069, or permission of instructor
Units: 2-3-1
Lecture: W2-4 (4-253) Lab: F1-4 (4-253)
______
Practical aspects of crystal structure determination from data collection strategies to data reduction and basic and advanced refinement problems of organic and inorganic molecules.
P. Mueller
Textbooks (Fall 2016)

5.068 Physical Inorganic Chemistry
______

Graduate (Spring); second half of term
Prereq: 5.03, 5.04
Units: 3-0-3
______
Discusses the physical methods used to probe the electronic and geometric structures of inorganic compounds, with additional techniques employed in the characterization of inorganic solids and surfaces. Includes vibrational spectroscopy, solid state and solution magnetochemical methods, Mössbauer spectroscopy, electron paramagnetic resonance spectroscopy, electrochemical methods, and a brief survey of surface techniques. Applications to current research problems in inorganic and solid-state chemistry.
M. Dinca

5.069 Crystal Structure Analysis
______

Graduate (Spring); first half of term
Prereq: 5.03, 5.04
Units: 2-0-4
______
Introduction to X-ray crystallography: symmetry in real and reciprocal space, space and Laue groups, geometry of diffraction, structure factors, phase problem, direct and Patterson methods, electron density maps, structure refinement, crystal growth, powder methods, limits of diffraction methods, structure data bases.
P. Mueller

5.07[J] Biological Chemistry I
______

Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject as20.507[J])
Prereq: 5.12
Units: 5-0-7
Credit cannot also be received for7.05
Lecture: MWF9 (4-370) Recitation: MW1 (36-372) or MW2 (36-372) or TR10 (36-144) or TR11 (36-144) +final
______
Chemical and physical properties of the cell and its building blocks. Structures of proteins and principles of catalysis. The chemistry of organic/inorganic cofactors required for chemical transformations within the cell. Basic principles of metabolism and regulation in pathways, including glycolysis, gluconeogenesis, fatty acid synthesis/degradation, pentose phosphate pathway, Krebs cycle and oxidative phosphorylation, DNA replication, and transcription and translation.
E. Nolan, A. Klibanov
Textbooks (Fall 2016)

5.08[J] Biological Chemistry II
______

Undergrad (Spring)
(Same subject as7.08[J])
(Subject meets with7.80)
Prereq: 5.12; 5.07 or 7.05
Units: 4-0-8
______
More advanced treatment of biochemical mechanisms that underlie biological processes. Topics include macromolecular machines such as the ribosome, the proteosome, fatty acid synthases as a paradigm for polyketide synthases and non-ribosomal polypeptide synthases, and polymerases. Emphasis is on experimental methods used to unravel these processes and how these processes fit into the cellular context and coordinate regulation.
E. Nolan

5.111 Principles of Chemical Science
______

Undergrad (Fall, Spring) Chemistry
Prereq: None
Units: 5-0-7
Credit cannot also be received for3.091,5.112,CC.5111,ES.3091,ES.5111,ES.5112
Lecture: MWF12 (10-250) Recitation: TR10 (36-112, 36-156) or TR11 (36-112, 4-159) or TR12 (4-159, 4-149, 36-112, 35-310, 36-144) or TR1 (36-144) or TR2 (4-145, 36-155, 36-112) or TR3 (4-145, 36-155) +final
______
Introduction to chemistry, with emphasis on basic principles of atomic and molecular electronic structure, thermodynamics, acid-base and redox equilibria, chemical kinetics, and catalysis. Introduction to the chemistry of biological, inorganic, and organic molecules.
Fall:M. Shoulders, T. Van Voorhis
Spring:M. Bawendi, M. Hong
Textbooks (Fall 2016)

5.112 Principles of Chemical Science
______

Undergrad (Fall) Chemistry
Prereq: None
Units: 5-0-7
Credit cannot also be received for3.091,5.111,CC.5111,ES.3091,ES.5111,ES.5112
Lecture: MWF11 (32-123) Recitation: TR11 (1-273) or TR12 (1-273, 13-4101) or TR2 (36-153, 26-204) +final
______
Introduction to chemistry for students with an unusually strong background in chemistry. Knowledge of calculus equivalent to 18.01 is recommended. Emphasis on basic principles of atomic and molecular electronic structure, thermodynamics, acid-base and redox equilibria, chemical kinetics, and catalysis. Applications of basic principles to problems in metal coordination chemistry, organic chemistry, and biological chemistry.
R. Schrock, S. Ceyer
Textbooks (Fall 2016)

5.12 Organic Chemistry I
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Chemistry (GIR)
Units: 5-0-7
Credit cannot also be received forCC.512
Lecture: MWF12 (32-123) Recitation: MW2 (36-156) or MW3 (36-156) or TR10 (8-205) or TR11 (8-205) or TR12 (36-372, 36-153) or TR1 (36-372, 36-153) or TR2 (36-372) or TR11 (4-265) or MW2 (26-302) +final
______
Introduction to organic chemistry. Development of basic principles to understand the structure and reactivity of organic molecules. Emphasis on substitution and elimination reactions and chemistry of the carbonyl group. Introduction to the chemistry of aromatic compounds.
Fall:J. Johnson, P. Ruiz-Castillo
Spring:R. L. Danheiser, P. Ruiz-Castillo
Textbooks (Fall 2016)

5.13 Organic Chemistry II
______

Undergrad (Fall)
Prereq: 5.12
Units: 5-0-7
Lecture: MWF12 (32-141) Recitation: MW2 (36-112) or MW3 (36-112) or TR10 (36-372) or TR11 (36-372, 13-3101) or TR1 (13-4101) or TR2 (13-4101) +final
______
Focuses on synthesis, structure determination, mechanism, and the relationships between structure and reactivity. Selected topics illustrate the role of organic chemistry in biological systems and in the chemical industry.
M. Movassaghi
Textbooks (Fall 2016)

5.24[J] Archaeological Science
______

Undergrad (Spring) HASS Social Sciences
(Same subject as3.985[J],12.011[J])
Prereq: Chemistry (GIR) or Physics I (GIR)
Units: 3-1-5
______
Pressing issues in archaeology as an anthropological science. Stresses the natural science and engineering methods archaeologists use to address these issues. Reconstructing time, space, and human ecologies provides one focus; materials technologies that transform natural materials to material culture provide another. Topics include 14C dating, ice core and palynological analysis, GIS and other remote sensing techniques for site location, soil micromorphology and site formation, sourcing of metal artifacts, and microstructural and mechanical analyses of cementitious materials used in ancient monumental buildings.
H. N. Lechtman

5.301 Chemistry Laboratory Techniques
______

Undergrad (IAP)
Prereq: Chemistry (GIR), permission of instructor
Units: 1-4-1 [P/D/F]
URL: http://chemistry.mit.edu/freshmen-pre-freshmen/chemistry-lab-techniques-5301
______
Practical training in basic chemistry laboratory techniques. Intended to provide freshmen with the skills necessary to undertake original research projects in chemistry. Freshmen only. Enrollment limited.
J. Dolhun

5.310 Laboratory Chemistry
______

Undergrad (Fall, Spring) Institute Lab
Prereq: None.Coreq: 5.12
Units: 2-8-2
Safety lecture mandatory. 9/7 or 9/8 at 1 pm room TBA. Lecture: TR12 (4-370) Lab: MW1-5 (4-430) or TR1-5 (4-430)
______
Introduces experimental chemistry for students who are not majoring in Course 5. Principles and applications of chemical laboratory techniques, including preparation and analysis of chemical materials, measurement of pH, gas and liquid chromatography, visible-ultraviolet spectrophotometry, infrared spectroscopy, kinetics, data analysis, and elementary synthesis. Enrollment limited.
J. Dolhun
Textbooks (Fall 2016)

5.35 Introduction to Experimental Chemistry
______

Undergrad (Fall, Spring) Institute Lab Can be repeated for credit
(Subject meets with5.35U)
Prereq: See module descriptions
Units arranged
URL: http://chemistry.mit.edu/urieca/urieca-module-signup-form-535535u
Select 4, 8 or 12 units. Safety lecture mandatory. 9/7 or 9/8 at 1 pm room TBA. Lecture: TR12 (4-153) Lab: MW1-5 (4-430) or TR1-5 (4-430)
______
This 12-unit subject consists of 3 modules, which may be taken during different terms. Modules and prerequisites are as follows:
Module 1 (Prereq: 5.111, 5.112 or 3.091) Survey of spectroscopy.
Module 2 (Prereq: 5.111, 5.112 or 3.091; Module 1) Synthesis of coordination compounds and kinetics.
Module 3 (Prereq: 5.111, 5.112 or 3.091; 5.12, Module 2) Fabrication of a polymeric light emitting device.
Enrollment limited; preference to Course 5 majors.
R. Field (Module 1), Y. Surendranath, M. Twardowski (Module 2), T. Swager (Module 3)
No textbook information available

5.35U Introduction to Experimental Chemistry
______

Undergrad (Fall, Spring) Can be repeated for credit
(Subject meets with5.35)
Prereq: See module descriptions under subject 5.35
Units arranged
URL: http://chemistry.mit.edu/urieca/urieca-module-signup-form-535535u
Select 4, 8 or 12 units. Safety lecture mandatory. 9/7 or 9/8 at 1 pm room TBA. Lecture: TR12 (4-153) Lab: MW1-5 (4-430) or TR1-5 (4-430)
______
For students who might not take all modules of 5.35. Consult department when choosing a version of 5.35. See description for 5.35. May be taken for 8 or 4 units and repeated for credit up to a total of 12 units.
R. W. Field (Module 1), Y. Surendranath, M. Twardowski (Module 2), T. Swager (Module 3)
No textbook information available

5.36 Biochemistry and Organic Laboratory
______

Undergrad (Fall, Spring) Can be repeated for credit
(Subject meets with5.36U)
Prereq: See module descriptions
Units arranged
URL: http://chemistry.mit.edu/urieca/urieca-module-signup-536536u
Select 4, 8 or 12 units. Safety lecture mandatory. 11/1 at 1 pm room 4-231. Lecture: TR12 (4-231) Lab: MW1-5 (4-430) or TR1-5 (4-430)
______
This 12-unit subject consists of 3 modules, which may be taken during different terms. Instruction and practice in the written and oral presentation of experimental results provided. Modules and prerequisites are as follows:
Module 4 Spring (Prereq: 5.07 or 7.05, Module 2 or 5.310, Module 5) Expression and Purification of Enzyme Mutants. Must be taken simultaneously with Module 5.
Module 5 Spring (Prereq: 5.07 or 7.05, Module 2 or 5.310, Module 4) Kinetics of Enzyme Inhibition. Must be taken simultaneously with Module 4.
Module 6 Fall (Prereq: 5.12, Module 2 or 5.310, 5.13) Organic Structure Determination.
Enrollment limited; preference to Course 5 majors.
Fall:R. L. Danheiser (Module 6)
Spring:B. Pentelute (Modules 4 & 5)
Textbooks (Fall 2016)

5.36U Biochemistry and Organic Laboratory
______

Undergrad (Fall, Spring) Can be repeated for credit
(Subject meets with5.36)
Prereq: See module descriptions under subject 5.36
Units arranged
URL: http://chemistry.mit.edu/urieca/urieca-module-signup-536536u
Select 4, 8 or 12 units. Safety lecture mandatory. 11/1 at 1 pm room 4-231. Lecture: TR12 (4-231) Lab: MW1-5 (4-430) or TR1-5 (4-430)
______
For students who might not take all modules of 5.36. Consult department when choosing a version of 5.36. See description for 5.36. May be taken for 8 or 4 units and repeated for credit up to a total of 12 units.
Fall:R. L. Danheiser (Module 6)
Spring:B. Pentelute (Modules 4 & 5)
Textbooks (Fall 2016)

5.37 Organic and Inorganic Laboratory
______

Undergrad (Fall, Spring) Can be repeated for credit
(Subject meets with5.37U)
Prereq: See module descriptions
Units arranged
URL: http://chemistry.mit.edu/urieca/urieca-module-signup-537537u
Select 4, 8 or 12 units. Safety lecture mandatory. 9/7 or 9/8 at 1 pm room TBA. Lecture: TR12 (4-231) Lab: MW1-5 (4-430) or TR1-5 (4-430)
______
This 12-unit subject consists of 3 modules, which may be taken during different terms. Modules and prerequisites are as follows:
Module 7 Spring (Prereq: 5.13, Module 6) Continuous Flow Chemistry: Sustainable Conversion of Reclaimed Vegetable Oil into Biodiesel.
Module 8 Fall (Prereq: 5.03, Module 2) Chemistry of Renewable Energy.
Module 9 Fall (Prereq: 5.03, Module 6, 5.61) Dinitrogen Cleavage.
Enrollment limited; preference to Course 5 majors.
Fall:Y. Surendranath (Module 8); C. C. Cummins (Module 9)
Spring:T. Jamison (Module 7)
No textbook information available

5.37U Organic and Inorganic Laboratory
______

Undergrad (Fall, Spring) Can be repeated for credit
(Subject meets with5.37)
Prereq: See module descriptions under subject 5.37
Units arranged
URL: http://chemistry.mit.edu/urieca/urieca-module-signup-537537u
Select 4, 8 or 12 units. Safety lecture mandatory. 9/7 or 9/8 at 1 pm room TBA. Lecture: TR12 (4-231) Lab: MW1-5 (4-430) or TR1-5 (4-430)
______
For students who might not take all modules of 5.37. Consult department when choosing a version of 5.37. See description for 5.37. May be taken for 8 or 4 units and repeated for credit up to a total of 12 units.
Fall:Y. Surendranath (Module 8); C. C. Cummins (Module 9)
Spring:T. Jamison (Module 7)
No textbook information available

5.38 Biological and Physical Chemistry Laboratory
______

Undergrad (Spring) Can be repeated for credit
Prereq: See module descriptions
Units arranged
URL: http://chemistry.mit.edu/urieca/urieca-module-signup-538
______
This 12-unit subject consists of 3 modules, which may be taken during different terms. Instruction and practice in the written and oral presentation of experimental results provided. Modules and prerequisites are as follows:
Module 10 (Prereq: 5.61, Module 6) Quantum Dots.
Module 11 (Prereq: 5.61, 5.07 or 7.05, Module 5) Time Resolved Molecular Spectroscopy.
Module 12 (Prereq: 5.07 or 7.05, Module 6)Fast Flow Peptide and Protein Synthesis.
Enrollment limited; preference to Course 5 majors.
M. G. Bawendi (Module 10), G. Schlau-Cohen (Module 11), B. Pentelute (Module 12)

5.43 Advanced Organic Chemistry
______

Undergrad (Fall)
Prereq: 5.13
Units: 4-0-8
Credit cannot also be received for5.53
Lecture: TR9.30-11 (4-257) Recitation: F11 (4-257) or F1 (4-257) +final
______
Reaction mechanisms in organic chemistry: methods of investigation, relation of structure to reactivity, and reactive intermediates. Photochemistry and organometallic chemistry, with an emphasis on fundamental reactivity, mechanistic studies, and applications in organic chemistry.
T. Swager
Textbooks (Fall 2016)

5.44 Organometallic Chemistry
______

Graduate (Spring); first half of term
Prereq: 5.43, 5.47, 5.061, or permission of instructor
Units: 2-0-4
______
Examination of the most important transformations of organotransition-metal species. Emphasizes basic mechanisms of their reactions, structure-reactivity relationships, and applications in synthesis.
K. Khan

5.45 Heterocyclic Chemistry
______

Graduate (Spring); second half of term
Prereq: 5.511, 5.53
Units: 2-0-4
______
Provides an introduction to the chemistry of heterocyclic compounds. Surveys synthesis and reactivity of the major classes of heterocyclic organic compounds. Discusses the importance of these molecules in the pharmaceutical and other industries.
S. Buchwald

5.46 NMR Spectroscopy and Organic Structure Determination
______

Graduate (Spring); first half of term
Prereq: 5.43
Units: 2-0-4
______
Applications of 1-D and 2-D1H and13C NMR spectroscopy to organic structure determination.
J. H. Simpson

5.47 Tutorial in Organic Chemistry
______

Graduate (Fall); partial term
Prereq: 5.43, permission of instructor
Units: 2-0-4 [P/D/F]
Ends Sep 30. Lecture: MWF9-11 (18-278, 18-578, 4-251)
______
Systematic review of basic principles concerned with the structure and transformations of organic molecules. Problem-solving workshop format. The program is intended primarily for first-year graduate students with a strong interest in organic chemistry. Meets during the month of September.
R. L. Danheiser
Textbooks (Fall 2016)


left arrow|5.00-5.4999|5.50-5.999, plus UROP and Theses|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 5: Chemistry
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Course 5: Chemistry
Fall 2016


5.511 Synthetic Organic Chemistry I
______

Graduate (Fall); partial term
Prereq: 5.43
Units: 3-0-9
Begins Oct 3. Lecture: MWF8.30-10 (4-159)
______
Introduction to the design of syntheses of complex organic compounds.
R. L. Danheiser
Textbooks (Fall 2016)

5.512 Synthetic Organic Chemistry II
______

Graduate (Spring); second half of term
Prereq: 5.511
Units: 2-0-4
______
General methods and strategies for the synthesis of complex organic compounds.
Staff

5.52 Advanced Biological Chemistry
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-2-8
Lecture: TR2.30-4.30 (8-119) Lab: TR1-5 (BEGINS OCT 31) (4-465)
______
Concepts and methods of biochemistry, with emphasis on quantitative aspects of problem analysis and fundamentals of experimental methods. Intended for first-year graduate students with a strong interest in biological chemistry.
A. M. Klibanov
No textbook information available

5.53 Molecular Structure and Reactivity
______

Graduate (Fall); partial term
Prereq: 5.13, 5.60
Units: 3-0-6
Credit cannot also be received for5.43
Begins Oct 3. Lecture: MWF10 (4-149)
______
Reaction mechanisms in organic chemistry: methods of investigation, relation of structure to reactivity, and reactive intermediates.
J. Van Humbeck
Textbooks (Fall 2016)

5.54[J] Frontiers in Chemical Biology
______

Graduate (Fall)
(Same subject as7.540[J],20.554[J])
Prereq: 5.13, 5.07, 7.06, permission of instructor
Units: 2-0-4
Lecture: R8.30-10 (4-231)
______
Introduction to current research at the interface of chemistry, biology, and bioengineering. Topics include imaging of biological processes, metabolic pathway engineering, protein engineering, mechanisms of DNA damage, RNA structure and function, macromolecular machines, protein misfolding and disease, metabolomics, and methods for analyzing signaling network dynamics. Lectures are interspersed with class discussions and student presentations based on current literature.
M. Shoulders
No textbook information available

5.56 Molecular Structure and Reactivity II
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: Permission of Instructor
Units: 2-0-4
______
Application of physical principles and methods to contemporary problems of interest in organic chemistry.
J. Johnson

5.561 Chemistry in Industry
______

Graduate (Spring); second half of term
Prereq: 5.03; 5.07 or 7.05; 5.13
Units: 2-0-4 [P/D/F]
______
Examination of recent advances in organic, biological, and inorganic and physical chemical research in industry. Taught in seminar format with participation by scientists from industrial research laboratories.
R. L. Danheiser

5.60 Thermodynamics and Kinetics
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR), Chemistry (GIR)
Units: 5-0-7
Lecture: MWF10 (4-370) Recitation: MW12 (36-372) or TR11 (36-153, 36-156) or TR12 (36-156, 2-146) or TR1 (2-146) or TR2 (2-146) +final
______
Equilibrium properties of macroscopic systems. Basic thermodynamics: state of a system, state variables. Work, heat, first law of thermodynamics, thermochemistry. Second and third law of thermodynamics: entropy and free energy, including the molecular basis for these thermodynamic functions. Phase equilibrium and properties of solutions. Chemical equilibrium of reactions in gas and solution phases. Rates of chemical reactions. Special attention to thermodynamics related to global energy issues.
Fall:M. Bawendi, A. Shalek
Spring:R. Field, A. Willard
Textbooks (Fall 2016)

5.61 Physical Chemistry
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Physics II (GIR), Calculus II (GIR), Chemistry (GIR)
Units: 5-0-7
Lecture: MWF10 (2-105) Recitation: MW12 (4-159) or TR11 (56-180) +final
______
Introductory quantum chemistry; particles and waves; wave mechanics; atomic structure and the Periodic Table; valence and molecular orbital theory; molecular structure; and photochemistry.
R. Field, M. Hong
Textbooks (Fall 2016)

5.62 Physical Chemistry
______

Undergrad (Spring)
Prereq: 5.60, 5.61
Units: 4-0-8
______
Elementary statistical mechanics; transport properties; kinetic theory; solid state; reaction rate theory; and chemical reaction dynamics.
S. Ceyer, J. Cao

5.64[J] Frontiers of Interdisciplinary Science in Human Health and Disease
______

Graduate (Spring)
(Same subject asHST.539[J])
Prereq: 5.13, 5.60; 5.07 or 7.05
Units: 3-0-9
______
Introduces major principles, concepts, and clinical applications of biophysics, biophysical chemistry, and systems biology. Emphasizes biological macromolecular interactions, biochemical reaction dynamics, and genomics. Discusses current technological frontiers and areas of active research at the interface of basic and clinical science. Provides integrated, interdisciplinary training and core experimental and computational methods in molecular biochemistry and genomics.
A. Shalek

5.68[J] Kinetics of Chemical Reactions
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as10.652[J])
Prereq: 5.62, 10.37, or 10.65
Units: 3-0-6
URL: http://web.mit.edu/10.652/www/
Lecture: TR11-12.30 (56-114)
______
Experimental and theoretical aspects of chemical reaction kinetics, including transition-state theories, molecular beam scattering, classical techniques, quantum and statistical mechanical estimation of rate constants, pressure-dependence and chemical activation, modeling complex reacting mixtures, and uncertainty/ sensitivity analyses. Reactions in the gas phase, liquid phase, and on surfaces are discussed with examples drawn from atmospheric, combustion, industrial, catalytic, and biological chemistry.
W. H. Green
Textbooks (Fall 2016)

5.697[J] Quantum Chemical Simulation
______

Undergrad (Fall)
(Same subject as10.437[J])
(Subject meets with5.698[J],10.637[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (14-0637)
______
Addresses both the theory and application of first-principles computer simulations methods (i.e., quantum, chemical, or electronic structure), including Hartree-Fock theory, density functional theory, and correlated wavefunction methods. Covers enhanced sampling, ab initio molecular dynamics, and transition-path-finding approaches as well as errors and accuracy in total and free energies. Discusses applications such as the study and prediction of properties of chemical systems, including heterogeneous, molecular, and biological catalysts (enzymes), and physical properties of materials. Students taking graduate version complete additional assignments.
H. J. Kulik
Textbooks (Fall 2016)

5.698[J] Quantum Chemical Simulation
______

Graduate (Fall)
(Same subject as10.637[J])
(Subject meets with5.697[J],10.437[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (14-0637)
______
Addresses both the theory and application of first-principles computer simulations methods (i.e., quantum, chemical, or electronic structure), including Hartree-Fock theory, density functional theory, and correlated wavefunction methods. Covers enhanced sampling, ab initio molecular dynamics, and transition-path-finding approaches as well as errors and accuracy in total and free energies. Discusses applications such as the study and prediction of properties of chemical systems, including heterogeneous, molecular, and biological catalysts (enzymes), and physical properties of materials. Students taking graduate version complete additional assignments.
H. J. Kulik
Textbooks (Fall 2016)

5.70[J] Statistical Thermodynamics
______

Graduate (Fall)
(Same subject as10.546[J])
Prereq: 5.60 or permission of instructor
Units: 3-0-9
Lecture: MW8.30-10 (4-231)
______
Develops classical equilibrium statistical mechanical concepts for application to chemical physics problems. Basic concepts of ensemble theory formulated on the basis of thermodynamic fluctuations. Examples of applications include Ising models, lattice models of binding, ionic and non-ionic solutions, liquid theory, polymer and protein conformations, phase transition, and pattern formation. Introduces computational techniques with examples of liquid and polymer simulations.
A. Willard, B. Zhang
Textbooks (Fall 2016)

5.72 Statistical Mechanics
______

Graduate (Spring); second half of term
Not offered regularly; consult department
Prereq: 5.70, 5.73, 18.075
Units: 2-0-4
______
Principles and methods of statistical mechanics. Classical and quantum statistics, grand ensembles, fluctuations, molecular distribution functions, and other topics in equilibrium statistical mechanics. Topics in thermodynamics and statistical mechanics of irreversible processes.
J. Cao

5.73 Introductory Quantum Mechanics I
______

Graduate (Fall)
Prereq: 5.61, 8.03, 18.03
Units: 3-0-9
Lecture: TR9.30-11 (1-150)
______
Presents the fundamental concepts of quantum mechanics: wave properties, uncertainty principles, Schrodinger equation, and operator and matrix methods. Includes applications to one-dimensional potentials (harmonic oscillator), three-dimensional centrosymetric potentials (hydrogen atom), and angular momentum and spin. Approximation methods include WKB, variational principle, and perturbation theory.
R. G. Griffin
Textbooks (Fall 2016)

5.74 Introductory Quantum Mechanics II
______

Graduate (Spring)
Prereq: 5.73
Units: 3-0-9
______
Time-dependent quantum mechanics and spectroscopy. Topics include perturbation theory, two-level systems, light-matter interactions, relaxation in quantum systems, correlation functions and linear response theory, and nonlinear spectroscopy.
K. Nelson, G. Schlau-Cohen

5.78 Biophysical Chemistry Techniques
______

Not offered academic year 2017-2018Graduate (Spring); first half of term
(Subject meets with7.71)
Prereq: 5.07 or 7.05
Units: 2-0-4
URL: http://web.mit.edu/5.78/www/
______
Presents principles of macromolecular crystallography that are essential for structure determinations. Topics include crystallization, diffraction theory, symmetry and space groups, data collection, phase determination methods, model building, and refinement. Discussion of crystallography theory complemented with exercises such as crystallization, data processing, and model building. Meets with 7.71 when offered concurrently. Enrollment limited.
C. Drennan, T. Schwartz

5.80 Advanced Topics of Current Special Interest
______

Graduate (Fall, Spring)
Prereq: 5.61 or 8.04; 18.03
Units: 3-0-9
TBA.
______
Advanced topics of current special interest.
Staff
No textbook information available

5.891 Independent Study in Chemistry for Undergraduates
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No textbook information available

5.892 Independent Study in Chemistry for Undergraduates
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Program of independent study under direction of Chemistry faculty member. May not substitute for required courses for the Chemistry major or minor.
Staff
No textbook information available

5.90 Problems in Chemistry
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Directed research and study of special chemical problems. For Chemistry graduate students only.
R. W. Field
No textbook information available

5.913 Seminar in Organic Chemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-1 [P/D/F]
Lecture: R EVE (4-6 PM) (6-120)
______
Discusses current journal publications in organic chemistry by graduate students and staff members.
R. L. Danheiser
No textbook information available

5.921 Seminar in Biological Chemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-1 [P/D/F]
Lecture: M EVE (4-6 PM) (4-270)
______
Discusses topics of current interest in biological chemistry by graduate students and staff.
M. Shoulders
No textbook information available

5.931 Seminar in Physical Chemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 5.60
Units: 2-0-1 [P/D/F]
Lecture: T EVE (4-6 PM) (6-120)
______
Discusses topics of current interest in physical chemistry by staff members and students.
A. Willard
No textbook information available

5.941 Seminar in Inorganic Chemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 5.03
Units: 2-0-1 [P/D/F]
Lecture: W EVE (4-6 PM) (4-370)
______
Discusses current research in inorganic chemistry by graduate students and staff.
S. Lippard
No textbook information available

5.95[J] Teaching College-Level Science and Engineering
______

Graduate (Fall)
(Same subject as1.95[J],7.59[J],8.395[J],18.094[J])
(Subject meets with2.978)
Prereq: None
Units: 2-0-2 [P/D/F]
URL: https://wikis.mit.edu/confluence/pages/viewpage.action?pageId=110876412
Lecture: R9-11 (4-149)
______
Participatory seminar focuses on the knowledge and skills necessary for teaching science and engineering in higher education. Topics include theories of adult learning; course development; promoting active learning, problemsolving, and critical thinking in students; communicating with a diverse student body; using educational technology to further learning; lecturing; creating effective tests and assignments; and assessment and evaluation. Students research and present a relevant topic of particular interest. Appropriate for both novices and those with teaching experience.
J. Rankin
No textbook information available

5.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of a PhD thesis; to be arranged by the student and an appropriate MIT faculty member.
R. W. Field
Textbooks arranged individually

5.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of original research under supervision of a chemistry faculty member, culminating with the preparation of a thesis. Ordinarily requires equivalent of two terms of research with chemistry department faculty member.
Staff
Textbooks arranged individually

5.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Program of research to be arranged by the student and a departmental faculty member. Research can be applied toward undergraduate thesis.
C. C. Cummins
Textbooks arranged individually

5.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Program of research to be arranged by the student and a departmental faculty member. May be taken for up to 12 units per term, not to exceed a cumulative total of 48 units. A 10-page paper summarizing research is required.
C. C. Cummins
Textbooks arranged individually


left arrow|5.00-5.4999|5.50-5.999, plus UROP and Theses|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 6: Electrical Engineering and Computer Science
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Course 6: Electrical Engineering and Computer Science
Fall 2016


Basic Undergraduate Subjects

6.00 Introduction to Computer Science and Programming
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: None
Units: 3-7-2
Lecture: MW3 (26-100) Lab: TBA +final
______
Introduction to computer science and programming for students with little or no programming experience. Students learn how to program and how to use computational techniques to solve problems. Topics include software design, algorithms, data analysis, and simulation techniques. Assignments are done using the Python programming language. Meets with 6.0001 first half of term and 6.0002 second half of term. Credit cannot also be received for 6.0001 or 6.0002. Final given during final exam week.
J. V. Guttag
Textbooks (Fall 2016)

6.0001 Introduction to Computer Science Programming in Python
______

Undergrad (Fall, Spring); first half of term
Prereq: None
Units: 2-3-1
Ends Oct 21. Lecture: MW3 (26-100) Recitation: F10 (36-112, 36-153) or F11 (36-112, 36-153) or F12 (36-153) or F1 (36-153) or F2 (36-153) or F3 (36-153) or F12 (36-112) or F1 (36-112) or F2 (36-112) or F3 (36-112) or F1 (36-156)
______
Introduction to computer science and programming for students with little or no programming experience. Students develop skills to program and use computational techniques to solve problems. Topics include the notion of computation, Python, simple algorithms and data structures, testing and debugging, and algorithmic complexity. Combination of 6.0001 and 6.0002 counts as REST subject. Final given in the seventh week of the term.
J. V. Guttag
Textbooks (Fall 2016)

6.0002 Introduction to Computational Thinking and Data Science
______

Undergrad (Fall, Spring); second half of term
Prereq: 6.0001 or permission of instructor
Units: 2-3-1
Begins Oct 24. Lecture: MW3 (26-100) Recitation: F10 (36-112, 36-153) or F11 (36-112, 36-153) or F12 (36-153) or F1 (36-153) or F2 (36-153) or F3 (36-153) or F12 (36-112) or F1 (36-112) or F2 (36-112) or F3 (36-112) or F1 (36-156) +final
______
Provides an introduction to using computation to understand real-world phenomena. Topics include plotting, stochastic programs, probability and statistics, random walks, Monte Carlo simulations, modeling data, optimization problems, and clustering. Combination of 6.0001 and 6.0002 counts as REST subject. Final given during final exam week.
J. V. Guttag
Textbooks (Fall 2016)

6.002 Circuits and Electronics
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Physics II (GIR);Coreq: 18.03 or 2.087
Units: 4-1-7
Lecture: TR11 (34-101) Lab: TBA Recitation: WF11 (26-310) or WF12 (26-310) or WF1 (26-310) or WF2 (26-310) +final
______
Fundamentals of the lumped circuit abstraction. Resistive elements and networks, independent and dependent sources, switches and MOS devices, digital abstraction, amplifiers, and energy storage elements. Dynamics of first- and second-order networks; design in the time and frequency domains; analog and digital circuits and applications. Design exercises. Occasional laboratory.
A. Agarwal, J. del Alamo, J. H. Lang, D. J. Perreault
Textbooks (Fall 2016)

6.003 Signals and Systems
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Physics II (GIR); 2.087 or 18.03
Units: 5-0-7
Lecture: TR12 (34-101) Lab: TBA Recitation: WF10 (26-210) or WF11 (26-210) or WF1 (36-144) or WF2 (36-144) +final
______
Presents the fundamentals of signal and system analysis. Topics include discrete-time and continuous-time signals, Fourier series and transforms, Laplace and Z transforms, and analysis of linear, time-invariant systems. Applications drawn broadly from engineering and physics, including audio and image processing, communications, and automatic control.
D. M. Freeman, Q. Hu, J. S. Lim
No textbook information available

6.004 Computation Structures
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Physics II (GIR)
Units: 4-0-8
URL: http://6004.mit.edu/
Lecture: TR1 (10-250) Recitation: WF10 (34-301, 13-4101) or WF11 (34-301, 13-4101) or WF12 (34-303, 36-155) or WF1 (34-303, 36-155) or WF2 (34-303, 13-5101) or WF3 (34-303, 13-5101)
______
Introduces architecture of digital systems, emphasizing structural principles common to a wide range of technologies. Multilevel implementation strategies; definition of new primitives (e.g., gates, instructions, procedures, and processes) and their mechanization using lower-level elements. Analysis of potential concurrency; precedence constraints and performance measures; pipelined and multidimensional systems. Instruction set design issues; architectural support for contemporary software structures.
S. A. Ward, C. J. Terman
No required or recommended textbooks

6.005 Elements of Software Construction
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: 6.01;Coreq: 6.042
Units: 4-0-8
Lecture: MW1-2.30,F1 (32-123)
______
Introduces fundamental principles and techniques of software development, i.e., how to write software that is safe from bugs, easy to understand, and ready for change. Topics include specifications and invariants; testing, test-case generation, and coverage; abstract data types and representation independence; design patterns for object-oriented programming; concurrent programming, including message passing and shared concurrency, and defending against races and deadlock; and functional programming with immutable data and higher-order functions. Includes weekly programming exercises and larger group programming projects. 12 Engineering Design Points.
D. N. Jackson, R. C. Miller
No required or recommended textbooks

6.006 Introduction to Algorithms
______

Undergrad (Fall, Spring)
Prereq: 6.042; 6.01 orCoreq: 6.009
Units: 4-0-8
Lecture: TR11 (26-100) Recitation: WF10 (34-304, 34-302, 35-310) or WF11 (34-304, 34-302, 36-155) or WF12 (34-301, 34-304) or WF1 (34-304, 5-134) or WF2 (5-134, 35-310) or WF3 (35-310) or WF4 (35-310) +final
______
Introduction to mathematical modeling of computational problems, as well as common algorithms, algorithmic paradigms, and data structures used to solve these problems. Emphasizes the relationship between algorithms and programming, and introduces basic performance measures and analysis techniques for these problems.
R. L. Rivest, S. Devadas
Textbooks (Fall 2016)

6.007 Electromagnetic Energy: From Motors to Solar Cells
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Physics II (GIR);Coreq: 2.087 or 18.03
Units: 5-1-6
Lecture: MWF1 (37-212) Lab: T EVE (7-9 PM) (38-601) or W EVE (7-9 PM) (38-601) +final
______
Discusses applications of electromagnetic and equivalent quantum mechanical principles to classical and modern devices. Covers energy conversion and power flow in both macroscopic and quantum-scale electrical and electromechanical systems, including electric motors and generators, electric circuit elements, quantum tunneling structures and instruments. Studies photons as waves and particles and their interaction with matter in optoelectronic devices, including solar cells and displays.
V. Bulovic, R. J. Ram
Textbooks (Fall 2016)

6.008 Introduction to Inference
______

Undergrad (Fall) Institute Lab
Prereq: Calculus II (GIR) or permission of instructor
Units: 4-4-4
F10-12 meets in 32-044. Lecture: MW10 (32-155) Lab: R3-5,F10-12 (35-225) Recitation: TR10 (3-442) or TR1 (34-302) or TR2 (34-302) +final
______
Introduces probabilistic modeling for problems of inference and machine learning from data, emphasizing analytical and computational aspects. Distributions, marginalization, conditioning, and structure; graphical representations. Belief propagation, decision-making, classification, estimation, and prediction. Sampling methods and analysis. Introduces asymptotic analysis and information measures. Substantial computational laboratory component explores the concepts introduced in class in the context of realistic contemporary applications. Students design inference algorithms, investigate their behavior on real data, and discuss experimental results.
P. Golland, G. W. Wornell
Textbooks (Fall 2016)

6.009 Fundamentals of Programming
(6.S04)
______

Undergrad (Fall, Spring) Institute Lab
Prereq: 6.0001
Units: 2-4-6
Lecture: T11-12.30 (54-100) Lab: F10-12 (35-225) or F1-3 (6-120) or F9-11 (3-333) or F1-3 (35-225) Recitation: W10-12 (32-124) or W1-3 (4-270) or W9-11 (35-225) or W1-3 (26-100)
______
Introduces fundamental concepts of programming. Designed to develop skills in applying basic methods from programming languages to abstract problems. Topics include programming and Python basics, computational concepts, software engineering, algorithmic techniques, data types, and recursion and tail recursion. Lab component consists of software design, construction, and implementation of design.
A. Chlipala, S. Devadas
No required or recommended textbooks

6.01 Introduction to EECS via Robot Sensing, Software and Control
______

Undergrad (Fall, Spring) Institute Lab
Prereq: 6.0001 or permission of instructor
Units: 2-4-6
URL: http://mit.edu/6.01/index.html
Lecture: T9.30-11 (4-270) Lab: T11-12.30,R2-5 (34-501) or T2-3.30,R9.30-12.30 (34-501) +final
______
An integrated introduction to electrical engineering and computer science, taught using substantial laboratory experiments with mobile robots. Key issues in the design of engineered artifacts operating in the natural world: measuring and modeling system behaviors; assessing errors in sensors and effectors; specifying tasks; designing solutions based on analytical and computational models; planning, executing, and evaluating experimental tests of performance; refining models and designs. Issues addressed in the context of computer programs, control systems, probabilistic inference problems, circuits and transducers, which all play important roles in achieving robust operation of a large variety of engineered systems.
D. M. Freeman, A. Hartz, L. P. Kaelbling, T. Lozano-Perez
No required or recommended textbooks

6.011 Signals, Systems and Inference
______

Undergrad (Spring)
Prereq: 6.041A
Units: 4-0-8
______
Covers signals, systems and inference in communication, control and signal processing. Topics include input-output and state-space models of linear systems driven by deterministic and random signals; time- and transform-domain representations in discrete and continuous time; and group delay. State feedback and observers. Probabilistic models; stochastic processes, correlation functions, power spectra, spectral factorization. Least-mean square error estimation; Wiener filtering. Hypothesis testing; detection; matched filters.
A. V. Oppenheim, G. C. Verghese

6.012 Microelectronic Devices and Circuits
______

Undergrad (Fall, Spring)
Prereq: 6.002
Units: 4-0-8
Lecture: TR11 (32-141) Recitation: WF1 (34-302) or WF2 (34-302) +final
______
Microelectronic device modeling, and basic microelectronic circuit analysis and design. Physical electronics of semiconductor junction and MOS devices. Relating terminal behavior to internal physical processes, developing circuit models, and understanding the uses and limitations of different models. Use of incremental and large-signal techniques to analyze and design transistor circuits, with examples chosen from digital circuits, linear amplifiers, and other integrated circuits. Design project.
A. I. Akinwande, D. A. Antoniadis, J. Kong, C. G. Sodini
Textbooks (Fall 2016)

6.013 Electromagnetics and Applications
______

Undergrad (Spring)
Prereq: Calculus II (GIR), Physics II (GIR)
Units: 3-3-6
______
Analysis and design of modern applications that employ electromagnetic phenomena for signals and power transmission in RF, microwaves, optical and wireless communication systems. Fundamentals include dynamic solutions for Maxwell's equations; electromagnetic power and energy, waves in media, guided waves, radiation, and diffraction; coupling to media and structures; resonance & filters; acoustic analogs. Labs include student hands-on activities from building to testing of devices and systems (e.g. radar) that reinforce lectures, with a focus on fostering creativity and debugging skills. 6.002 and 6.007 are recommended but not required.
L. Daniel, M. R. Watts

6.02 Introduction to EECS via Communications Networks
______

Undergrad (Fall) Institute Lab
Prereq: 6.0001
Units: 4-4-4
Lecture: MW2 (34-101) Recitation: TR10 (34-304) or TR11 (34-304) or TR12 (34-304) or TR1 (34-304) or TR2 (34-301) or TR3 (34-301) or TR10 (24-112) or TR11 (26-210) +final
______
Studies key concepts, systems, and algorithms to reliably communicate data in settings ranging from the cellular phone network and the Internet to deep space. Weekly laboratory experiments explore these areas in depth. Topics presented in three modules - bits, signals, and packets - spanning the multiple layers of a communication system. Bits module includes information, entropy, data compression algorithms, and error correction with block and convolutional codes. Signals module includes modeling physical channels and noise, signal design, filtering and detection, modulation, and frequency-division multiplexing. Packets module includes switching and queuing principles, media access control, routing protocols, and data transport protocols.
H. Balakrishnan, K. LaCurts, G. C. Verghese,
No required or recommended textbooks

6.021[J] Cellular Neurophysiology
______

Undergrad (Fall)
(Same subject as2.791[J],20.370[J])
(Subject meets with2.794[J],6.521[J],20.470[J],HST.541[J])
Prereq: Physics II (GIR); 18.03; 2.005, 6.002, 6.003, 6.071, 10.301, 20.110, or permission of instructor
Units: 5-2-5
Lecture: MWF10 (32-144) Lab: TBA Recitation: T12 (34-303) or T4 (34-302) +final
______
Integrated overview of the biophysics of cells from prokaryotes to neurons, with a focus on mass transport and electrical signal generation across cell membrane. First half of course focuses on mass transport through membranes: diffusion, osmosis, chemically mediated, and active transport. Second half focuses on electrical properties of cells: ion transport to action potentials in electrically excitable cells. Synaptic transmission. Electrical properties interpreted via kinetic and molecular properties of single voltage-gated ion channels. Laboratory and computer exercises illustrate the concepts. Students taking graduate version complete different assignments. Preference to juniors and seniors.
J. Han, T. Heldt, J. Voldman
Textbooks (Fall 2016)

6.022[J] Quantitative Systems Physiology
______

Undergrad (Spring)
(Same subject as2.792[J],HST.542[J])
(Subject meets with2.796[J],6.522[J])
Prereq: Physics II (GIR), 18.03, or permission of instructor
Units: 4-2-6
URL: http://web.mit.edu/6.022j/www/
______
Application of the principles of energy and mass flow to major human organ systems. Mechanisms of regulation and homeostasis. Anatomical, physiological and pathophysiological features of the cardiovascular, respiratory and renal systems. Systems, features and devices that are most illuminated by the methods of physical sciences. Laboratory work includes some animal studies. Students taking graduate version complete additional assignments. 2 Engineering Design Points.
T. Heldt, R. G. Mark, C. M. Stultz

6.023[J] Fields, Forces and Flows in Biological Systems
______

Undergrad (Spring)
(Same subject as2.793[J],20.330[J])
Prereq: Physics II (GIR); 2.005, 6.021, or permission of instructor,Coreq: 20.309
Units: 4-0-8
______
Introduction to electric fields, fluid flows, transport phenomena and their application to biological systems. Flux and continuity laws, Maxwell's equations, electro-quasistatics, electro-chemical-mechanical driving forces, conservation of mass and momentum, Navier-Stokes flows, and electrokinetics. Applications include biomolecular transport in tissues, electrophoresis, and microfluidics.
J. Han, S. Manalis

6.024[J] Molecular, Cellular, and Tissue Biomechanics
______

Undergrad (Spring)
(Same subject as2.797[J],3.053[J],20.310[J])
Prereq: 2.370 or 2.772J; 18.03 or 3.016; Biology (GIR)
Units: 4-0-8
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, A. J. Grodzinsky, K. Van Vliet

6.025[J] Medical Device Design
______

Undergrad (Fall)
(Same subject as2.750[J])
(Subject meets with2.75[J],6.525[J],HST.552[J])
Prereq: 2.72, 6.101, 6.111, 6.115, 22.071, or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/2.75/
Lecture: MW1-2.30 (3-270)
______
Application of mechanical and electrical engineering fundamentals to the design of medical devices that address clinical needs. Throughout the term, students work in small teams on a major project to translate a clinical challenge into a proof-of-concept prototype device. Students conduct user analysis, develop design specifications, and follow a structured process to cultivate creative designs and apply analytical techniques to optimize them. They deepen their understanding of art and intellectual property by researching prior representations. Develops practical skills in prototyping and testing as well as project management. Includes lectures, problem sets and exams that focus on design fundamentals. Instruction and practice in written and oral communication provided. Students taking graduate version complete additional assignments. Enrollment limited.
A. H. Slocum, G. Hom
No required or recommended textbooks

6.027[J] Biomolecular Feedback Systems
______

Undergrad (Spring)
(Same subject as2.180[J])
(Subject meets with2.18[J],6.557[J])
Prereq: 18.03, Biology (GIR), or permission of instructor
Units: 3-0-9
______
Comprehensive introduction to dynamics and control of biomolecular systems with emphasis on design/analysis techniques from control theory. Provides a review of biology concepts, regulation mechanisms, and models. Covers basic enabling technologies, engineering principles for designing biological functions, modular design techniques, and design limitations. Students taking graduate version complete additional assignments.
D. Del Vecchio

6.03 Introduction to EECS via Medical Technology
______

Undergrad (Spring) Institute Lab
Prereq: Calculus II (GIR), Physics II (GIR)
Units: 4-4-4
______
Explores biomedical signals generated from electrocardiograms, glucose detectors or ultrasound images, and magnetic resonance images. Topics include physical characterization and modeling of systems in the time and frequency domains; analog and digital signals and noise; basic machine learning including decision trees, clustering, and classification; and introductory machine vision. Labs designed to strengthen background in signal processing and machine learning. Students design and run structured experiments, and develop and test procedures through further experimentation.
C. M. Stultz, E. Adalsteinsson

6.031 Elements of Software Construction
(New)
______

Undergrad (Spring)
Prereq: 6.009
Units: 5-0-10
______
Introduces fundamental principles and techniques of software development: how to write software that is safe from bugs, easy to understand, and ready for change. Topics include specifications and invariants; testing, test-case generation, and coverage; abstract data types and representation independence; design patterns for object-oriented programming; concurrent programming, including message passing and shared concurrency, and defending against races and deadlock; and functional programming with immutable data and higher-order functions. Includes weekly programming exercises and larger group programming projects.
M. Goldman, R. C. Miller

6.033 Computer System Engineering
______

Undergrad (Spring)
Prereq: 6.004; 6.005 or 6.009
Units: 5-1-6
URL: http://web.mit.edu/6.033/www/
______
Topics on the engineering of computer software and hardware systems: techniques for controlling complexity; strong modularity using client-server design, operating systems; performance, networks; naming; security and privacy; fault-tolerant systems, atomicity and coordination of concurrent activities, and recovery; impact of computer systems on society. Case studies of working systems and readings from the current literature provide comparisons and contrasts. Includes a single, semester-long design project. Students engage in extensive written communication exercises. Enrollment may be limited.
K. LaCurts, M. F. Kaashoek, H. Balakrishnan

6.034 Artificial Intelligence
______

Undergrad (Fall)
Prereq: 6.0001
Units: 4-3-5
URL: http://courses.csail.mit.edu/6.034/
Lecture: MWF10 (10-250) Recitation: M11 (26-302, 34-301, 34-302, 34-304) or M12 (34-302) or M11 (36-372) or M12 (34-304) or M1 (34-303, 34-304) or M2 (34-301, 34-304) or M3 (34-304) or M11 (38-166) or T10 (34-301, 34-302) or T11 (34-301) or T12 (26-328, 34-301) or T1 (34-301, 34-303) or T2 (34-303) or T3 (34-303) or M12 (38-166, 26-302) or T11 (26-302) +final
______
Introduces representations, methods, and architectures used to build applications and to account for human intelligence from a computational point of view. Covers applications of rule chaining, constraint propagation, constrained search, inheritance, statistical inference, and other problem-solving paradigms. Also addresses applications of identification trees, neural nets, genetic algorithms, support-vector machines, boosting, and other learning paradigms. Considers what separates human intelligence from that of other animals.
P. H. Winston
No textbook information available

6.035 Computer Language Engineering
______

Undergrad (Fall)
Prereq: 6.004; 6.005 or 6.031
Units: 4-4-4
URL: http://web.mit.edu/6.035/6035.html
Lecture: MWF11 (3-370) Recitation: TR11 (4-149)
______
Analyzes issues associated with the implementation of higher-level programming languages. Fundamental concepts, functions, and structures of compilers. The interaction of theory and practice. Using tools in building software. Includes a multi-person project on compiler design and implementation.
M. C. Rinard
No textbook information available

6.036 Introduction to Machine Learning
______

Undergrad (Spring)
(Subject meets with6.862)
Prereq: 6.0001
Units: 4-0-8
______
Introduces principles, algorithms, and applications of machine learning from the point of view of modeling and prediction; formulation of learning problems; representation, over-fitting, generalization; clustering, classification, probabilistic modeling; and methods such as support vector machines, hidden Markov models, and Bayesian networks. Students taking graduate version complete additional assignments.
R. Barzilay, T. Jaakkola, L. P. Kaelbling

6.037 Structure and Interpretation of Computer Programs
______

Undergrad (IAP)
Prereq: None
Units: 1-0-5 [P/D/F]
______
Studies the structure and interpretation of computer programs which transcend specific programming languages. Demonstrates thought patterns for computer science using Scheme. Includes weekly programming projects. Enrollment may be limited.
Staff

6.041A Introduction to Probability I
(New)
______

Undergrad (Fall, Spring); first half of term
(Subject meets with6.431A)
Prereq: Calculus II (GIR)
Units: 2-0-4
Ends Oct 21. Lecture: MW12 (34-101) Recitation: TR11 (24-121) or TR12 (24-121) or TR1 (24-121) or TR2 (24-121)
______
Provides an introduction to probability theory and the modeling and analysis of probabilistic systems. Probabilistic models, conditional probability. Discrete and continuous random variables. Expectation and conditional expectation. Limit Theorems. Students taking graduate version complete additional assignments. Combination of 6.041A and 6.041B counts as a REST subject.
P. Jaillet, J. N. Tsitsiklis
No textbook information available

6.041B Introduction to Probability II
(New)
______

Undergrad (Fall, Spring); second half of term
(Subject meets with6.431B)
Prereq: 6.041A
Units: 2-0-4
Begins Oct 24. Lecture: MW12 (34-101) Recitation: TR11 (24-121) or TR12 (24-121) or TR1 (24-121) or TR2 (24-121) +final
______
Building on 6.041A, further discusses topics in probability. Bayesian estimation and hypothesis testing. Elements of statistical inference. Bernoulli and Poisson processes. Markov chains. Students taking graduate version complete additional assignments. Combination of 6.041A and 6.041B counts as a REST subject.
P. Jaillet, J. N. Tsitsiklis
No textbook information available

6.042[J] Mathematics for Computer Science
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
(Same subject as18.062[J])
Prereq: Calculus I (GIR)
Units: 5-0-7
URL: http://theory.csail.mit.edu/classes/6.042
Lecture: TR2.30-4 (26-100) Recitation: WF9 (38-166) or WF10 (38-166) or WF11 (38-166) or WF12 (38-166) or WF1 (38-166) or WF2 (38-166) or WF3 (38-166) or WF4 (38-166) or WF10 (13-3101) or WF11 (13-3101) or WF12 (13-3101) or WF1 (13-3101) or WF2 (13-3101) or WF3 (13-3101) or WF4 (13-3101) or WF10 (26-168) or WF11 (26-168) or WF12 (26-168) or WF1 (26-168) or WF2 (26-168) or WF3 (26-168) or WF4 (26-168) or WF11 (24-112) or WF12 (24-112) or WF1 (24-112) or WF9 (26-168) +final
______
Elementary discrete mathematics for computer science and engineering. Emphasis on mathematical definitions and proofs as well as on applicable methods. Topics include formal logic notation, proof methods; induction, well-ordering; sets, relations; elementary graph theory; asymptotic notation and growth of functions; permutations and combinations, counting principles; discrete probability. Further selected topics include recursive definition and structural induction, state machines and invariants, integer congruences, recurrences, generating functions.
F. T. Leighton, A. R. Meyer, A. Moitra
No required or recommended textbooks

6.045[J] Automata, Computability, and Complexity
______

Undergrad (Spring)
(Same subject as18.400[J])
Prereq: 6.042
Units: 4-0-8
URL: http://math.mit.edu/classes/18.400
______
Provides an introduction to some of the central ideas of theoretical computer science, including circuits, finite automata, Turing machines and computability, efficient algorithms and reducibility, the P versus NP problem, NP-completeness, the power of randomness, cryptography, computational learning theory, and quantum computing. Examines the classes of problems that can and cannot be solved in various computational models.
S. Aaronson

6.046[J] Design and Analysis of Algorithms
______

Undergrad (Fall, Spring)
(Same subject as18.410[J])
Prereq: 6.006
Units: 4-0-8
URL: http://math.mit.edu/classes/18.410
Lecture: TR11-12.30 (32-123) Recitation: F10 (4-159) or F11 (4-159, 4-149, 36-156) or F12 (36-156, 4-159) or F1 (4-159, 4-149) or F2 (35-308) or F3 (35-308) +final
______
Techniques for the design and analysis of efficient algorithms, emphasizing methods useful in practice. Topics include sorting; search trees, heaps, and hashing; divide-and-conquer; dynamic programming; greedy algorithms; amortized analysis; graph algorithms; and shortest paths. Advanced topics may include network flow; computational geometry; number-theoretic algorithms; polynomial and matrix calculations; caching; and parallel computing.
E. Demaine, M. Goemans
Textbooks (Fall 2016)

6.047 Computational Biology: Genomes, Networks, Evolution
______

Undergrad (Fall)
(Subject meets with6.878[J],HST.507[J])
Prereq: 6.006, 6.041B, Biology (GIR); or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (32-141) Recitation: F3 (4-237)
______
Covers the algorithmic and machine learning foundations of computational biology, combining theory with practice. Principles of algorithm design, influential problems and techniques, and analysis of large-scale biological datasets. Topics include (a) genomes: sequence analysis, gene finding, RNA folding, genome alignment and assembly, database search; (b) networks: gene expression analysis, regulatory motifs, biological network analysis; (c) evolution: comparative genomics, phylogenetics, genome duplication, genome rearrangements, evolutionary theory. These are coupled with fundamental algorithmic techniques including: dynamic programming, hashing, Gibbs sampling, expectation maximization, hidden Markov models, stochastic context-free grammars, graph clustering, dimensionality reduction, Bayesian networks.
M. Kellis
No textbook information available

6.049[J] Evolutionary Biology: Concepts, Models and Computation
______

Undergrad (Spring)
(Same subject as7.33[J])
Prereq: 7.03; 6.0001 or permission of instructor
Units: 3-0-9
______
Explores and illustrates how evolution explains biology, with an emphasis on computational model building for analyzing evolutionary data. Covers key concepts of biological evolution, including adaptive evolution, neutral evolution, evolution of sex, genomic conflict, speciation, phylogeny and comparative methods, life's history, coevolution, human evolution, and evolution of disease.
R. Berwick, D. Bartel

6.050[J] Information, Entropy, and Computation
______

Undergrad (Spring)
(Same subject as2.110[J])
Prereq: Physics I (GIR)
Units: 3-0-6
______
Explores the ultimate limits to communication and computation, with an emphasis on the physical nature of information and information processing. Topics include information and computation, digital signals, codes, and compression. Biological representations of information. Logic circuits, computer architectures, and algorithmic information. Noise, probability, and error correction. The concept of entropy applied to channel capacity and to the second law of thermodynamics. Reversible and irreversible operations and the physics of computation. Quantum computation.
P. Penfield, Jr., S. Lloyd

6.057 Introduction to MATLAB
______

Undergrad (IAP)
Prereq: None
Units: 1-0-2 [P/D/F]
______
Accelerated introduction to MATLAB and its popular toolboxes. Lectures are interactive, with students conducting sample MATLAB problems in real time. Includes problem-based MATLAB assignments. Students must provide their own laptop and software. Enrollment limited.
Staff

6.058 Introduction to Signals and Systems, and Feedback Control
______

Undergrad (IAP)
Prereq: Calculus II (GIR) or permission of instructor
Units: 2-2-2 [P/D/F]
______
Introduces fundamental concepts for 6.003, including Fourier and Laplace transforms, convolution, sampling, filters, feedback control, stability, and Bode plots. Students engage in problem solving, using Mathematica and MATLAB software extensively to help visualize processing in the time frequency domains.
Staff

6.061 Introduction to Electric Power Systems
______

Not offered academic year 2017-2018Undergrad (Spring)
(Subject meets with6.690)
Prereq: 6.002, 6.013
Units: 3-0-9
______
Electric circuit theory with application to power handling electric circuits. Modeling and behavior of electromechanical devices, including magnetic circuits, motors, and generators. Operational fundamentals of synchronous, induction and DC machinery. Interconnection of generators and motors with electric power transmission and distribution circuits. Power generation, including alternative and sustainable sources. Students taking graduate version complete additional assignments.
J. L. Kirtley, Jr.

6.07[J] Projects in Microscale Engineering for the Life Sciences
______

Undergrad (Spring)
Not offered regularly; consult department
(Same subject asHST.410[J])
Prereq: None
Units: 2-4-3
______
A project-based introduction to manipulating and characterizing cells and biological molecules using microfabricated tools. In the first half of the term, students perform laboratory exercises designed to introduce the design, manufacture, and use of microfluidic channels; techniques for sorting and manipulating cells and biomolecules; and making quantitative measurements using optical detection and fluorescent labeling. In the second half of the term, students work in small groups to design and test a microfluidic device to solve a real-world problem of their choosing. Includes exercises in written and oral communication and team building. Limited to 20; preference to freshmen.
D. Freeman, M. Gray

6.070[J] Electronics Project Laboratory
______

Undergrad (Fall, Spring)
(Same subject asEC.120[J])
Prereq: None
Units: 2-2-2
Lecture: M EVE (7-10 PM) (4-409)
______
Intuition-based introduction to electronics, electronic components and test equipment such as oscilloscopes, meters (voltage, resistance inductance, capacitance, etc.), and signal generators. Emphasizes individual instruction and development of skills, such as soldering, assembly, and troubleshooting. Students design, build, and keep a small electronics project to put their new knowledge into practice. Intended for students with little or no previous background in electronics. Enrollment may be limited.
J. Bales
No required or recommended textbooks

6.071[J] Electronics, Signals, and Measurement
______

Undergrad (Spring) Rest Elec in Sci & Tech
(Same subject as22.071[J])
Prereq: 18.03
Units: 3-3-6
URL: http://www.mit.edu:8001/courses/6.071/
______
Provides the knowledge necessary for reading schematics and designing, building, analyzing, and testing fundamental analog and digital circuits. Students construct interactive examples and explore the practical uses of electronics in engineering and experimental science, including signals and measurement fundamentals. Uses state-of-the-art hardware and software for data acquisition, analysis, and control. Suitable for students with little or no previous background in electronics.
A. White

6.072[J] Introduction to Digital Electronics
______

Undergrad (Fall, Spring)
(Same subject asEC.110[J])
Prereq: None
Units: 0-3-3 [P/D/F]
Lecture: M EVE (7-10 PM) (4-402)
______
Design your own circuits for times when off-the-shelf solutions are not available. Seminar begins with assembly of a utility board. Weekly labs cover digital logic gates, memory elements, and finite-state machine design. Seminar concludes with a team-based design project. Preference given to freshmen. Maximum of 10 students per term, lottery at the first class session if oversubscribed .
J. Bales
No required or recommended textbooks

6.073[J] Creating Video Games
______

Undergrad (Spring) HASS Arts
(Same subject asCMS.611[J])
Prereq: 6.01, CMS.301, or CMS.608
Units: 3-3-6
______
Introduces students to the complexities of working in small, multidisciplinary teams to develop video games. Covers creative design and production methods, stressing design iteration and regular testing across all aspects of game development (design, visual arts, music, fiction, and programming). Assumes a familiarity with current video games, and the ability to discuss games critically. Previous experience in audio design, visual arts, or project management recommended. Limited to 24.
P. Tan, S. Verrilli, R. Eberhardt

6.S062 Special Subject in Electrical Engineering and Computer Science
______

Undergrad (Fall) Can be repeated for credit
Prereq: None
Units arranged
URL: http://www.eecs.mit.edu/academics-admissions/academic-information/subject-updates-st-2016
Lecture: M3-5 (36-153)
______
Basic undergraduate subjects not offered in the regular curriculum.
Consult Department
No textbook information available

6.S063, 6.S064 Special Subject in Electrical Engineering and Computer Science
______

Undergrad (Fall) Can be repeated for credit
Prereq: None
Units arranged
6.S064: URL: https://www.eecs.mit.edu/academics-admissions/academic-information/subject-updates-ft-2016/6s064
6.S063: TBA.
6.S064: Lecture: TR11 (34-101) +final
______
Basic undergraduate subjects not offered in the regular curriculum.
Consult Department
6.S063: No textbook information available
6.S064: No textbook information available

6.S08 Special Subject: Interconnected Embedded Systems
______

Undergrad (Spring) Institute Lab
Prereq: None
Units: 1-5-6
______
Introduction to embedded systems in the context of connected devices, wearables and the "Internet of Things". Topics include microcontrollers, energy utilization, algorithmic efficiency, interfacing with sensors, networking, cryptography, local versus distributed computation, data analytics, and 3D printing. Students will design, make, and program an internet-connected wearable device. Final project where student teams will design and demo their own cloud-connected wearable system. Licensed for Spring 2016 by the Committee on Curricula. Enrollment limited; preference to first- and second-year students.
J. Voldman, J. D. Steinmeyer

6.S076-6.S084 Special Subject in Electrical Engineering and Computer Science
______

Undergrad (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
6.S082: URL: http://www.eecs.mit.edu/academics-admissions/academic-information/subject-updates-ft-2016
6.S080: TBA.
Subject Cancelled 6.S082 Cancelled
6.S084: Lecture: MW1-2.30 (1-150)
______
Covers subject matter not offered in the regular curriculum. Consult department to learn of offerings for a particular term.
Consult Department
6.S080: No required or recommended textbooks
6.S084: No textbook information available

6.S085-6.S099 Special Subject in Electrical Engineering and Computer Science
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Covers subject matter not offered in the regular curriculum. Consult department to learn of offerings for a particular term.
Consult Department

Undergraduate Laboratory Subjects

6.100 Electrical Engineering and Computer Science Project
______

Undergrad (Fall, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Individual experimental work related to electrical engineering and computer science. Student must make arrangements with a project supervisor and file a proposal endorsed by the supervisor. Departmental approval required. Written report to be submitted upon completion of work.
Consult Department Undergraduate Office
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

6.101 Introductory Analog Electronics Laboratory
______

Undergrad (Spring) Institute Lab
Prereq: 6.002 or 6.071
Units: 2-9-1
URL: http://web.mit.edu/6.101/www/
______
Introductory experimental laboratory explores the design, construction, and debugging of analog electronic circuits. Lectures and laboratory projects in the first half of the course investigate the performance characteristics of semiconductor devices (diodes, BJTs, and MOSFETs) and functional analog building blocks, including single-stage amplifiers, op amps, small audio amplifier, filters, converters, sensor circuits, and medical electronics (ECG, pulse-oximetry). Projects involve design, implementation, and presentation in an environment similar to that of industry engineering design teams. Instruction and practice in written and oral communication provided. Opportunity to simulate real-world problems and solutions that involve tradeoffs and the use of engineering judgment. Engineers from local companies help students with their design projects.
G. Hom

6.111 Introductory Digital Systems Laboratory
______

Undergrad (Fall) Institute Lab
Prereq: 6.002, 6.071, or 16.004
Units: 3-7-2
Lecture: TR2.30-4 (32-124) Lab: TBA
______
Lectures and labs on digital logic, flip flops, PALs, FPGAs, counters, timing, synchronization, and finite-state machines prepare students for the design and implementation of a final project of their choice: games, music, digital filters, wireless communications, video, or graphics. Extensive use of Verilog for describing and implementing digital logic designs.
A. P. Chandrakasan, G. P. Hom
No required or recommended textbooks

6.115 Microcomputer Project Laboratory
______

Undergrad (Spring) Institute Lab
(Subject meets with6.1151)
Prereq: 6.002, 6.003, 6.004, or 6.007
Units: 3-6-3
______
Introduces analysis and design of embedded systems. Microcontrollers provide adaptation, flexibility, and real-time control. Emphasizes construction of complete systems, including a five-axis robot arm, a fluorescent lamp ballast, a tomographic imaging station (e.g., a CAT scan), and a simple calculator. Presents a wide range of basic tools, including software and development tools, programmable system on chip, peripheral components such as A/D converters, communication schemes, signal processing techniques, closed-loop digital feedback control, interface and power electronics, and modeling of electromechanical systems. Includes a sequence of assigned projects, followed by a final project of the student's choice, emphasizing creativity and uniqueness. Provides instruction in written and oral communication. Students taking independent inquiry version 6.1151 expand the scope of their laboratory project.
S. B. Leeb

6.1151 Microcomputer Project Laboratory - Independent Inquiry
(New)
______

Undergrad (Spring)
(Subject meets with6.115)
Prereq: 6.002, 6.003, 6.004, or 6.007
Units: 3-9-3
______
Introduces analysis and design of embedded systems. Microcontrollers provide adaptation, flexibility, and real-time control. Emphasizes construction of complete systems, including a five-axis robot arm, a fluorescent lamp ballast, a tomographic imaging station (e.g., a CAT scan), and a simple calculator. Presents a wide range of basic tools, including software and development tools, programmable system on chip, peripheral components such as A/D converters, communication schemes, signal processing techniques, closed-loop digital feedback control, interface and power electronics, and modeling of electromechanical systems. Includes a sequence of assigned projects, followed by a final project of the student's choice, emphasizing creativity and uniqueness. Provides instruction in written and oral communication. Students taking independent inquiry version 6.1151 expand the scope of their laboratory project.
S. B. Leeb

6.117 Introduction to Electrical Engineering Lab Skills
______

Undergrad (IAP)
Prereq: None
Units: 1-3-2 [P/D/F]
______
Introduces basic electrical engineering concepts, components, and laboratory techniques. Covers analog integrated circuits, power supplies, and digital circuits. Lab exercises provide practical experience in constructing projects using multi-meters, oscilloscopes, logic analyzers, and other tools. Includes a project in which students build a circuit to display their own EKG. Enrollment limited.
G. P. Hom

6.123[J] Bioinstrumentation Project Lab
______

Undergrad (Spring)
(Same subject as20.345[J])
Prereq: Biology (GIR), and 2.004 or 6.003; or 20.309; or permission of instructor
Units: 2-7-3
______
In-depth examination of instrumentation design, principles and techniques for studying biological systems, from single molecules to entire organisms. Lectures cover optics, advanced microscopy techniques, electronics for biological measurement, magnetic resonance imaging, computed tomography, MEMs, microfluidic devices, and limits of detection. Students select two lab exercises during the first half of the semester and complete a final design project in the second half. Lab emphasizes design process and skillful realization of a robust system. Enrollment limited; preference to Course 20 majors and minors.
E. Boyden, M. Jonas, S. F. Nagle, P. So, S. Wasserman, M. F. Yanik

6.129[J] Biological Circuit Engineering Laboratory
______

Undergrad (Spring) Institute Lab
(Same subject as20.129[J])
Prereq: Biology (GIR), Calculus II (GIR)
Units: 2-8-2
______
Students assemble individual genes and regulatory elements into larger-scale circuits; they experimentally characterize these circuits in yeast cells using quantitative techniques, including flow cytometry, and model their results computationally. Emphasizes concepts and techniques to perform independent experimental and computational synthetic biology research. Discusses current literature and ongoing research in the field of synthetic biology. Instruction and practice in oral and written communication provided. Enrollment limited.
T. Lu, R. Weiss

6.131 Power Electronics Laboratory
______

Undergrad (Fall) Institute Lab
(Subject meets with6.1311)
Prereq: 6.002, 6.003, or 6.007
Units: 3-6-3
Lecture: TR1 (34-101) Lab: W3 (34-101)
______
Introduces the design and construction of power electronic circuits and motor drives. Laboratory exercises include the construction of drive circuitry for an electric go-cart, flash strobes, computer power supplies, three-phase inverters for AC motors, and resonant drives for lamp ballasts and induction heating. Basic electric machines introduced include DC, induction, and permanent magnet motors, with drive considerations. Provides instruction in written and oral communication. Students taking independent inquiry version 6.1131 expand the scope of their laboratory project.
S. B. Leeb
Textbooks (Fall 2016)

6.1311 Power Electronics Laboratory - Independent Inquiry
(New)
______

Undergrad (Fall)
(Subject meets with6.131)
Prereq: 6.002, 6.003, or 6.007
Units: 3-9-3
Lecture: TR1 (34-101) Lab: W3 (34-101)
______
Introduces the design and construction of power electronic circuits and motor drives. Laboratory exercises include the construction of drive circuitry for an electric go-cart, flash strobes, computer power supplies, three-phase inverters for AC motors, and resonant drives for lamp ballasts and induction heating. Basic electric machines introduced include DC, induction, and permanent magnet motors, with drive considerations. Provides instruction in written and oral communication. Students taking independent inquiry version 6.1131 expand the scope of their laboratory project.
S. B. Leeb
Textbooks (Fall 2016)

6.141[J] Robotics: Science and Systems
______

Undergrad (Spring) Institute Lab
(Same subject as16.405[J])
Prereq: 1.00 or 6.0001; 2.003, 6.005, 6.006, 6.009, or 16.06; or permission of instructor
Units: 2-6-4
URL: http://courses.csail.mit.edu/rss/
______
Presents concepts, principles, and algorithms for sensing and computation related to the physical world. Topics include motion planning, geometric reasoning, kinematics and dynamics, state estimation, tracking, map building, manipulation, human-robot interaction, fault diagnosis, and embedded system development. Students specify and design a small-scale yet complex robot capable of real-time interaction with the natural world. Students engage in extensive written and oral communication exercises. Enrollment limited.
S. Karaman, D. Rus

6.146 Mobile Autonomous Systems Laboratory: MASLAB
______

Undergrad (IAP) Can be repeated for credit
Prereq: None
Units: 2-2-2 [P/D/F]
______
Autonomous robotics contest emphasizing technical AI, vision, mapping and navigation from a robot-mounted camera. Few restrictions are placed on materials, sensors, and/or actuators enabling teams to build robots very creatively. Teams should have members with varying engineering, programming and mechanical backgrounds. Culminates with a robot competition at the end of IAP. Enrollment limited.
Staff

6.147 The Battlecode Programming Competition
______

Undergrad (IAP) Can be repeated for credit
Prereq: None
Units: 2-0-4 [P/D/F]
URL: http://www.battlecode.org
______
Artificial Intelligence programming contest in Java. Student teams program virtual robots to play Battlecode, a real-time strategy game. Competition culminates in a live BattleCode tournament. Assumes basic knowledge of programming.
Staff

6.148 Web Programming Competition
______

Undergrad (IAP) Can be repeated for credit
Prereq: Permission of instructor
Units: 1-0-5 [P/D/F]
______
Teams compete to build the most functional and user-friendly website. Competition is judged by industry experts and includes novice and advanced divisions. Prizes awarded. Lectures and workshops cover website basics. Enrollment limited.
Staff

6.149 Introduction to Programming Using Python
______

Not offered academic year 2016-2017Undergrad (IAP)
Prereq: None
Units: 3-0-3 [P/D/F]
______
Fact-paced introduction to Python programming language for students with little or no programming experience. Covers both function and object-oriented concepts. Includes weekly lab exercises and final project. Enrollment limited.
Staff

6.150 Mobile Applications Competition
______

Undergrad (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 2-2-2 [P/D/F]
______
Student teams design and build an Android application based on a given theme. Lectures and labs led by experienced students and leading industry experts, covering the basics of Android development, concepts and tools to help participants build great apps. Contest culminates with a public presentation in front of a judging panel comprised of professional developers and MIT faculty. Prizes awarded. Enrollment limited.
Staff

6.151 iOS Game Design and Development Competition
______

Undergrad (IAP)
Prereq: None
Units: 2-2-2 [P/D/F]
______
Introduction to iOS game design and development for students already familiar with object-oriented programming. Provides a set of basic tools (Objective-C and Cocos2D) and exposure to real-world issues in game design. Working in small teams, students complete a final project in which they create their own iPhone game. At the end of IAP, teams present their games in competition for prizes awarded by a judging panel of gaming experts.
Staff

6.152[J] Micro/Nano Processing Technology
______

Undergrad (Fall)
(Same subject as3.155[J])
Prereq: Permission of instructor
Units: 3-4-5
Lecture: MW2.30-4 (32-124)
______
Introduces the theory and technology of micro/nano fabrication. Lectures and laboratory sessions on basic processing techniques such as vacuum processes, lithography, diffusion, oxidation, and pattern transfer. Students fabricate MOS capacitors, nanomechanical cantilevers, and microfluidic mixers. Emphasis on the interrelationships between material properties and processing, device structure, and the electrical, mechanical, optical, chemical or biological behavior of devices. Provides background for thesis work in micro/nano fabrication. Students engage in extensive written and oral communication exercises.
L. F. Velasquez-Garcia, J. Michel
Textbooks (Fall 2016)

6.161 Modern Optics Project Laboratory
______

Undergrad (Fall) Institute Lab
(Subject meets with6.637)
Prereq: 6.003
Units: 3-5-4
URL: http://web.mit.edu/6.161/www/index.html
Lecture: TR2.30-4 (34-304) Lab: TBA
______
Lectures, laboratory exercises and projects on optical signal generation, transmission, detection, storage, processing and display. Topics include polarization properties of light; reflection and refraction; coherence and interference; Fraunhofer and Fresnel diffraction; holography; Fourier optics; coherent and incoherent imaging and signal processing systems; optical properties of materials; lasers and LEDs; electro-optic and acousto-optic light modulators; photorefractive and liquid-crystal light modulation; display technologies; optical waveguides and fiber-optic communication systems; photodetectors. Students may use this subject to find an advanced undergraduate project. Students engage in extensive oral and written communcation exercises. Recommended prerequisites: 6.007 or 8.03.
C. Warde
No textbook information available

6.163 Strobe Project Laboratory
______

Undergrad (Fall, Spring) Institute Lab
Prereq: Physics II (GIR) or permission of instructor
Units: 2-8-2
Lecture: MW12 (4-149) Lab: TBA
______
Application of electronic flash sources to measurement and photography. First half covers fundamentals of photography and electronic flashes, including experiments on application of electronic flash to photography, stroboscopy, motion analysis, and high-speed videography. Students write four extensive lab reports. In the second half, students work in small groups to select, design, and execute independent projects in measurement or photography that apply learned techniques. Project planning and execution skills are discussed and developed over the term. Students engage in extensive written and oral communication exercises. Enrollment limited.
J. K. Vandiver, J. W. Bales
No required or recommended textbooks

6.169 Theory and Application of Circuits and Electronics
______

Undergrad (Fall, Spring)
Prereq: None.Coreq: 6.002
Units: 1-1-1
Lecture: F3 (4-231) Recitation: TBA
______
Building on the framework of 6.002, provides a deeper understanding of the theory and applications of circuits and electronics.
A. Agarwal, J. del Alamo, J. H. Lang, D. J. Perreault
No textbook information available

6.170 Software Studio
______

Undergrad (Fall)
Prereq: 6.006; 6.005 or 6.031
Units: 4-0-8
URL: http://www.mit.edu/~6.170/
Lecture: MW2.30-4 (32-123) Recitation: R1 (38-166) or R2 (38-166) or R3 (38-166) or R11 (66-144) or R12 (66-144) or R1 (66-144) or R2 (66-144) or R3 (66-144) or R10 (38-166) or R11 (38-166) or R12 (38-166) or R4 (38-166)
______
Covers design and implementation of software systems, using web applications as the platform. Emphasizes the role of conceptual design in achieving clarity, simplicity, and modularity. Students complete open-ended individual assignments and a major team project. Enrollment may be limited.
D. N. Jackson
No textbook information available

6.172 Performance Engineering of Software Systems
______

Undergrad (Fall)
(Subject meets with6.871)
Prereq: 6.004, 6.006; 6.005 or 6.031
Units: 3-12-3
Lecture: TR2.30-4 (34-101) Lab: F10-12 (4-265) or F1-3 (4-265) or F3-5 (4-265) or F10-12 (24-307) or F1-3 (34-301) or F3-5 (34-301) or F2-4 (34-304) or F3-5 (36-155)
______
Project-based introduction to building efficient, high-performance and scalable software systems. Topics include performance analysis, algorithmic techniques for high performance, instruction-level optimizations, vectorization, cache and memory hierarchy optimization, and parallel programming. Students taking graduate version complete additional assignments.
S. Amarasinghe, C. E. Leiserson
No textbook information available

6.175 Constructive Computer Architecture
______

Undergrad (Fall)
Prereq: 6.004
Units: 3-8-1
Lecture: MWF3 (34-302)
______
Illustrates a constructive (as opposed to a descriptive) approach to computer architecture. Topics include combinational and pipelined arithmetic-logic units (ALU), in-order pipelined microarchitectures, branch prediction, blocking and unblocking caches, interrupts, virtual memory support, cache coherence and multicore architectures. Labs in a modern Hardware Design Language (HDL) illustrate various aspects of microprocessor design, culminating in a term project in which students present a multicore design running on an FPGA board.
Arvind
No textbook information available

6.176 Pokerbots Competition
______

Undergrad (IAP) Can be repeated for credit
Prereq: None
Units: 1-0-5 [P/D/F]
______
Build autonomous poker players and aquire the knowledge of the game of poker. Showcase decision making skills, apply concepts in mathematics, computer science and economics. Provides instruction in programming, game theory, probability and statistics and machine learning. Concludes with a final competition and prizes. Enrollment limited
Staff

6.177 Building Programming Experience in Python
______

Not offered academic year 2016-2017Undergrad (IAP)
Prereq: None
Units: 1-0-5 [P/D/F]
______
Preparation for 6.01 aimed to sharpen skills in program design, implementation, and debugging in Python. Programming intensive, with one short structured assignment and a supervised, but highly individual, mandatory project presentation. Intended for students with some elementary programming experience (equivalent to AP Computer Science). Enrollment limited.
Staff

6.178 Introduction to Software Engineering in Java
______

Undergrad (IAP)
Prereq: None
Units: 1-1-4 [P/D/F]
______
Covers the fundamentals of Java, helping students develop intuition about object-oriented programming. Focuses on developing working software that solves real problems. Designed for students with little or no programming experience. Concepts covered useful to 6.005. Enrollment limited.
Staff

6.179 Introduction to C and C++
______

Undergrad (IAP)
Prereq: None
Units: 3-3-0 [P/D/F]
______
Fast-paced introduction to the C and C++ programming languages. Intended for those with experience in other languages who have never used C or C++. Students complete daily assignments, a small-scale individual project, and a mandatory online diagnostic test. Enrollment limited.
Staff

6.182 Psychoacoustics Project Laboratory
______

Undergrad (Spring) Institute Lab
Prereq: None
Units: 3-6-3
______
Introduces the methods used to measure human auditory abilities. Discusses auditory function, principles of psychoacoustic measurement, models for psychoacoustic performance, and experimental techniques. Project topics: absolute and differential auditory sensitivity, operating characteristics of human observers, span of auditory judgment, adaptive measurement procedures, and scaling sensory magnitudes. Knowledge of probability helpful. Students engage in extensive written and oral communication exercises.
L. D. Braida

6.S183-6.S192 Special Laboratory Subject in Electrical Engineering and Computer Science
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Laboratory subject that covers content not offered in the regular curriculum. Consult department to learn of offerings for a particular term.
Consult Department

6.S193-6.S198 Special Laboratory Subject in Electrical Engineering and Computer Science
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
6.S194: URL: http://www.eecs.mit.edu/academics-admissions/academic-information/subject-updates-st-2016
______
Laboratory subject that covers content not offered in the regular curriculum. Consult department to learn of offerings for a particular term.
D. M. Freeman

Senior Projects

6.UAP Undergraduate Advanced Project
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 6.UAT
Units: 0-6-0
URL: http://www.eecs.mit.edu/ug/uap.html
Consult department TBA.
______
Research project for those students completing the SB degree, to be arranged by the student and an appropriate MIT faculty member. Students who register for this subject must consult the department undergraduate office. Students engage in extensive written communications exercises.
Consult Department Undergraduate Office
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

6.UAR Seminar in Undergraduate Advanced Research
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: 6.UR
Units: 2-0-4
URL: https://superurop.eecs.mit.edu/
Lecture: R4 (32-123)
______
Instruction in effective undergraduate research, including choosing and developing a research topic, surveying previous work and publications, research topics in EECS, industry best practices, design for robustness, technical presentation, authorship and collaboration, and ethics. Material covered over both fall and spring terms. Students engage in extensive written and oral communication exercises, in the context of an approved advanced research project. May be repeated for credit for a maximum of 12 units.
A. P. Chandrakasan, D. M. Freeman
No required or recommended textbooks

6.UAT Oral Communication
______

Undergrad (Fall, Spring)
Prereq: None
Units: 3-0-6
URL: https://courses.csail.mit.edu/6.UAT/main.php
Lecture: MW1 (34-101)
______
Provides instruction in aspects of effective technical oral presentations and exposure to communication skills useful in a workplace setting. Students create, give and revise a number of presentations of varying length targeting a range of different audiences.
T. L. Eng
No textbook information available

6.URS Undergraduate Research in Electrical Engineering and Computer Science
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
Consult department TBA.
______
Year-long individual research project arranged with appropriate faculty member or approved supervisor. Forms and instructions for the proposal and final report are available in the EECS Undergraduate Office.
A. P. Chandrakasan, D. M. Freeman
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

Advanced Undergraduate Subjects and Graduate Subjects by Area

Systems Science and Control Engineering

6.207[J] Networks
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Social Sciences
(Same subject as14.15[J])
Prereq: 6.041B or 14.30
Units: 4-0-8
______
Highlights common principles that permeate the functioning of diverse technological, economic and social networks. Utilizes three sets of tools for analyzing networks--random graph models, optimization, and game theory--to study informational and learning cascades; economic and financial networks; social influence networks; formation of social groups; communication networks and the Internet; consensus and gossiping; spread and control of epidemics; control and use of energy networks; and biological networks.
Consult Department Headquarters

6.231 Dynamic Programming and Stochastic Control
______

Graduate (Spring)
Prereq: 6.041B or 18.204; 18.100A, 18.100B, or 18.100Q
Units: 3-0-9
URL: http://web.mit.edu/6.231/www/6231.html
______
Sequential decision-making via dynamic programming. Unified approach to optimal control of stochastic dynamic systems and Markovian decision problems. Applications in linear-quadratic control, inventory control, resource allocation, scheduling, and planning. Optimal decision making under perfect and imperfect state information. Certainty equivalent, open loop-feedback control, rollout, model predictive control, aggregation, and other suboptimal control methods. Infinite horizon problems: discounted, stochastic shortest path, average cost, and semi-Markov models. Value and policy iteration. Abstract models in dynamic programming. Approximate/neurodynamic programming. Simulation based methods. Discussion of current research on the solution of large-scale problems.
J. N. Tsitsiklis

6.241[J] Dynamic Systems and Control
______

Graduate (Spring)
(Same subject as16.338[J])
Prereq: 6.003, 18.06
Units: 4-0-8
______
Linear, discrete- and continuous-time, multi-input-output systems in control, related areas. Least squares and matrix perturbation problems. State-space models, modes, stability, controllability, observability, transfer function matrices, poles and zeros, and minimality. Internal stability of interconnected systems, feedback compensators, state feedback, optimal regulation, observers, and observer-based compensators. Measures of control performance, robustness issues using singular values of transfer functions. Introductory ideas on nonlinear systems. Recommended prerequisite: 6.302.
M. A. Dahleh, A. Megretski, E. Frazzoli

6.245 Multivariable Control Systems
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.241 or 16.31
Units: 3-0-9
URL: http://web.mit.edu/6.245/www/index.html
______
Computer-aided design methodologies for synthesis of multivariable feedback control systems. Performance and robustness trade-offs. Model-based compensators; Q-parameterization; ill-posed optimization problems; dynamic augmentation; linear-quadratic optimization of controllers; H-infinity controller design; Mu-synthesis; model and compensator simplification; nonlinear effects. Computer-aided (MATLAB) design homework using models of physical processes.
A. Megretski

6.246, 6.247 Advanced Topics in Control
______

Graduate (Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Advanced study of topics in control. Specific focus varies from year to year.
Consult Department

6.248, 6.249 Advanced Topics in Numerical Methods
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Advanced study of topics in numerical methods. Specific focus varies from year to year.
Consult Department

6.251[J] Introduction to Mathematical Programming
______

Graduate (Fall)
(Same subject as15.081[J])
Prereq: 18.06
Units: 4-0-8
Lecture: TR1-2.30 (32-155) Recitation: F10 (36-156) or F12 (32-144)
______
Introduction to linear optimization and its extensions emphasizing both methodology and the underlying mathematical structures and geometrical ideas. Covers classical theory of linear programming as well as some recent advances in the field. Topics: simplex method; duality theory; sensitivity analysis; network flow problems; decomposition; integer programming; interior point algorithms for linear programming; and introduction to combinatorial optimization and NP-completeness.
J. N. Tsitsiklis, D. Bertsimas
Textbooks (Fall 2016)

6.252[J] Nonlinear Optimization
______

Graduate (Spring)
(Same subject as15.084[J])
Prereq: 18.06; 18.100A, 18.100B, or 18.100C
Units: 4-0-8
______
Unified analytical and computational approach to nonlinear optimization problems. Unconstrained optimization methods include gradient, conjugate direction, Newton, sub-gradient and first-order methods. Constrained optimization methods include feasible directions, projection, interior point methods, and Lagrange multiplier methods. Convex analysis, Lagrangian relaxation, nondifferentiable optimization, and applications in integer programming. Comprehensive treatment of optimality conditions and Lagrange multipliers. Geometric approach to duality theory. Applications drawn from control, communications, power systems, and resource allocation problems.
R. M. Freund, D. P. Bertsekas, G. Perakis

6.253 Convex Analysis and Optimization
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.06; 18.100A, 18.100B, or 18.100C
Units: 3-0-9
______
Core analytical issues of continuous optimization, duality, and saddle point theory, and development using a handful of unifying principles that can be easily visualized and readily understood. Discusses in detail the mathematical theory of convex sets and functions which are the basis for an intuitive, highly visual, geometrical approach to the subject. Convex optimization algorithms focus on large-scale problems, drawn from several types of applications, such as resource allocation and machine learning. Includes batch and incremental subgradient, cutting plane, proximal, and bundle methods.
D. P. Bertsekas

6.254 Game Theory with Engineering Applications
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.041B
Units: 4-0-8
______
Introduction to fundamentals of game theory and mechanism design with motivations for each topic drawn from engineering applications (including distributed control of wireline/wireless communication networks, transportation networks, pricing). Emphasis on the foundations of the theory, mathematical tools, as well as modeling and the equilibrium notion in different environments. Topics include normal form games, supermodular games, dynamic games, repeated games, games with incomplete/imperfect information, mechanism design, cooperative game theory, and network games.
A. Ozdaglar

6.255[J] Optimization Methods
______

Graduate (Fall)
(Same subject as15.093[J],IDS.200[J])
Prereq: 18.06
Units: 4-0-8
Lecture: TR2.30-4 (32-123) Recitation: W3 (66-168) or F1 (66-144) +final
______
Introduces the principal algorithms for linear, network, discrete, robust, nonlinear, dynamic optimization and optimal control. Emphasizes methodology and the underlying mathematical structures. Topics include the simplex method, network flow methods, branch and bound and cutting plane methods for discrete optimization, optimality conditions for nonlinear optimization, interior point methods for convex optimization, Newton's method, heuristic methods, and dynamic programming and optimal control methods.
D. Bertsimas, P. Parrilo
Textbooks (Fall 2016)

6.256 Algebraic Techniques and Semidefinite Optimization
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.251 or 6.255
Units: 3-0-9
______
Theory and computational techniques for optimization problems involving polynomial equations and inequalities with particular, emphasis on the connections with semidefinite optimization. Develops algebraic and numerical approaches of general applicability, with a view towards methods that simultaneously incorporate both elements, stressing convexity-based ideas, complexity results, and efficient implementations. Examples from several engineering areas, in particular systems and control applications. Topics include semidefinite programming, resultants/discriminants, hyperbolic polynomials, Groebner bases, quantifier elimination, and sum of squares.
P. Parrilo

6.260, 6.261 Advanced Topics in Communications
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Advanced study of topics in communications. Specific focus varies from year to year.
Consult Department

6.262 Discrete Stochastic Processes
______

Graduate (Spring)
Prereq: 6.041B, 6.431B or 18.204
Units: 4-0-8
______
Review of probability and laws of large numbers; Poisson counting process and renewal processes; Markov chains (including Markov decision theory), branching processes, birth-death processes, and semi-Markov processes; continuous-time Markov chains and reversibility; random walks, martingales, and large deviations; applications from queueing, communication, control, and operations research.
R. G. Gallager, V. W. S. Chan

6.263[J] Data-Communication Networks
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as16.37[J])
Prereq: 6.041B or 18.204
Units: 3-0-9
______
Provides an introduction to data networks with an analytic perspective, using telephone networks, wireless networks, optical networks, the Internet and data centers as primary applications. Presents basic tools for modeling and performance analysis accompanied by elementary, meaningful simulations. Develops insights for large networks by means of simple approximations. Draws upon concepts from queueing theory and optimization.
E. Modiano, D. Shah

6.265[J] Advanced Stochastic Processes
______

Graduate (Spring)
(Same subject as15.070[J])
Prereq: 6.431B, 15.085J, 18.100A, 18.100B, or 18.100Q
Units: 3-0-9
______
Analysis and modeling of stochastic processes. Topics include measure theoretic probability, martingales, filtration, and stopping theorems; elements of large deviations theory; Brownian motion and reflected Brownian motion; stochastic integration and Ito calculus; functional limit theorems. Applications to finance theory, insurance, queueing and inventory models.
D. Gamarnik, G. Bresler

6.267 Heterogeneous Networks: Architecture, Transport, Proctocols, and Management
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.041B or 6.042
Units: 4-0-8
______
Introduction to modern heterogeneous networks and the provision of heterogeneous services. Architectural principles, analysis, algorithmic techniques, performance analysis, and existing designs are developed and applied to understand current problems in network design and architecture. Begins with basic principles of networking. Emphasizes development of mathematical and algorithmic tools; applies them to understanding network layer design from the performance and scalability viewpoint. Concludes with network management and control, including the architecture and performance analysis of interconnected heterogeneous networks. Provides background and insight to understand current network literature and to perform research on networks with the aid of network design projects.
V. W. S. Chan, R. G. Gallager

6.268 Network Science and Models
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 6.041B, 18.06
Units: 3-0-9
______
Introduces the main mathematical models used to describe large networks and dynamical processes that evolve on networks. Static models of random graphs, preferential attachment, and other graph evolution models. Epidemic propagation, opinion dynamics, social learning, and inference in networks. Applications drawn from social, economic, natural, and infrastructure networks, as well as networked decision systems such as sensor networks.
J. N. Tsitsiklis, P. Jaillet


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Produced: 26-SEP-2016 05:10 PMFall 2016 Course 6: Electrical Engineering and Computer Science
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Course 6: Electrical Engineering and Computer Science
Fall 2016


Electronics, Computers, and Systems

6.301 Solid-State Circuits
______

Undergrad (Fall)
Prereq: 6.012
Units: 3-2-7
URL: http://web.mit.edu/6.301/www/
Lecture: TR1-2.30 (32-124)
______
Analysis and design of transistor circuits, based directly on the semiconductor physics and transistor circuit models developed in 6.012. High-frequency and low-frequency design calculations and simulation of multistage transistor circuits. Trans-linear circuits. Introduction to operational-amplifier design and application. Some previous laboratory experience assumed.
H. S. Lee
Textbooks (Fall 2016)

6.302 Feedback System Design
______

Undergrad (Spring)
(Subject meets with6.320)
Prereq: 6.003, 2.003, or 16.002
Units: 4-2-6
URL: http://web.mit.edu/6.302/www/
______
Learn-by-design introduction to continuous and discrete-time system modeling and feedback control. Topics include performance metrics; time- and frequency-domain model extraction and classical control; and basic state-space control. Students apply the control concepts in weekly labs and in a midterm project. Labs involve designing circuits and software, and using sensors and a high-performance microcontroller, to address control problems, such as positioning a motor- or propeller-actuated robot arm, reducing distortion in a PWM-based audio amplifier, eliminating field crosstalk for a magnetic-resonance imager, stabilizing magnetic levitation, balancing a two-wheel vehicle. Students taking graduate version complete additional assignments and an extra lab on observer-based state-space control. Intended for students who have previous laboratory experience with electronic systems.
J. D. Steinmeyer, J. K. White

6.320 Feedback System Design
(New)
______

Graduate (Spring)
(Subject meets with6.302)
Prereq: 6.003, 2.004, 2.04A, or 16.002
Units: 4-2-6
______
Learn-by-design introduction to continuous and discrete-time system modeling and feedback control. Topics include performance metrics; time- and frequency-domain model extraction and classical control; and basic state-space control. Students apply the control concepts in weekly labs and in a midterm project. Labs involve designing circuits and software, and using sensors and a high-performance microcontroller, to address control problems, such as positioning a motor- or propeller-actuated robot arm, reducing distortion in a PWM-based audio amplifier, eliminating field crosstalk for a magnetic-resonance imager, stabilizing magnetic levitation, balancing a two-wheel vehicle. Students taking graduate version complete additional assignments and an extra lab on observer-based state-space control. Intended for students who have previous laboratory experience with electronic systems. students taking graduate version complete additional assignments.
J. D. Steinmeyer, J. K. White

6.332, 6.333 Advanced Topics in Circuits
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
6.332: URL: https://www.eecs.mit.edu//academics-admissions/academic-information/subject-updates-st-2013?shib-logout=1
______
Advanced study of topics in circuits. Specific focus varies from year to year. Consult department for details.
Consult Department

6.334 Power Electronics
______

Graduate (Spring)
Prereq: 6.012
Units: 3-0-9
URL: http://web.mit.edu/course/6/6.334/
______
The application of electronics to energy conversion and control. Modeling, analysis, and control techniques. Design of power circuits including inverters, rectifiers, and dc-dc converters. Analysis and design of magnetic components and filters. Characteristics of power semiconductor devices. Numerous application examples, such as motion control systems, power supplies, and radio-frequency power amplifiers.
D. J. Perreault

6.335[J] Fast Methods for Partial Differential and Integral Equations
______

Graduate (Fall)
(Same subject as18.336[J])
Prereq: 6.336, 16.920, 18.085, 18.335, or permission of instructor
Units: 3-0-9
Lecture: MW9.30-11 (2-146)
______
Unified introduction to the theory and practice of modern, near linear-time, numerical methods for large-scale partial-differential and integral equations. Topics include preconditioned iterative methods; generalized Fast Fourier Transform and other butterfly-based methods; multiresolution approaches, such as multigrid algorithms and hierarchical low-rank matrix decompositions; and low and high frequency Fast Multipole Methods. Example applications include aircraft design, cardiovascular system modeling, electronic structure computation, and tomographic imaging.
C. Perez
No required or recommended textbooks

6.336[J] Introduction to Numerical Simulation
______

Graduate (Fall)
(Same subject as2.096[J],16.910[J])
Prereq: 18.03 or 18.06
Units: 3-3-6
Lecture: MW1-2.30 (32-141)
______
Introduction to computational techniques for the simulation of a large variety of engineering and physical systems. Applications are drawn from aerospace, mechanical, electrical, chemical engineering, biology, and materials science. Topics include mathematical formulations (techniques for automatic assembly of mathematical problems from physics' principles); sparse, direct and iterative solution techniques for linear systems; Newton and Homotopy methods for nonlinear problems; discretization methods for ordinary, time-periodic and partial differential equations; accelerated methods for integral equations; techniques for automatic generation of compact dynamical system models and model order reduction.
L. Daniel, J. K. White
No required or recommended textbooks

6.337[J] Introduction to Numerical Methods
______

Graduate (Spring)
(Same subject as18.335[J])
Prereq: 18.03 or 18.034; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.335
______
Advanced introduction to numerical linear algebra and other central algorithms of scientific computation. Topics include direct and iterative methods for linear systems, eigenvalue and QR/SVD factorizations, stability and accuracy, floating-point arithmetic, sparse matrices, preconditioning, and the memory considerations underlying modern linear-algebra software. Techniques for local and global nonlinear optimization, including quasi-Newton methods, trust regions, branch-and-bound, and multistart algorithms. Chebyshev approximations, numerical integration, and FFTs. A modern high-level language, Julia, is introduced for problem sets.
W. Shin

6.338[J] Parallel Computing
______

Graduate (Fall)
(Same subject as18.337[J])
Prereq: 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://beowulf.csail.mit.edu/18.337/index.html
Lecture: MW2-3.30 (4-237)
______
Interdisciplinary introduction to computing with Julia. Covers scientific computing and data analysis problems. Combines knowledge from computer science and computational science illustrating Julia's new approach to scientific computing. Sample scientific computing topics include dense and sparse linear algebra, Fourier transforms, data handling, and N-body problems. Provides direct experience with programming traditional-style supercomputing as well as working with modern cloud computing stacks.
A. Edelman
No textbook information available

6.339[J] Numerical Methods for Partial Differential Equations
______

Graduate (Fall)
(Same subject as2.097[J],16.920[J])
Prereq: 18.03 or 18.06
Units: 3-0-9
Lecture: MW9.30-11 (4-163)
______
Covers the fundamentals of modern numerical techniques for a wide range of linear and nonlinear elliptic, parabolic, and hyperbolic partial differential and integral equations. Topics include mathematical formulations; finite difference, finite volume, finite element, and boundary element discretization methods; and direct and iterative solution techniques. The methodologies described form the foundation for computational approaches to engineering systems involving heat transfer, solid mechanics, fluid dynamics, and electromagnetics. Computer assignments requiring programming.
Q. Wang, J. K. White
No textbook information available

6.341 Discrete-Time Signal Processing
______

Graduate (Fall)
Prereq: 6.011
Units: 4-0-8
URL: http://web.mit.edu/6.341/www/
Lecture: TR11-12.30 (32-124) Recitation: F11 (4-145) or F2 (4-145) +final
______
Representation, analysis, and design of discrete time signals and systems. Decimation, interpolation, and sampling rate conversion. Noise shaping. Flowgraph structures for DT systems. Lattice filters. Time- and frequency-domain design techniques for IIR and FIR filters. Parametric signal modeling, linear prediction, and the relation to lattice filters. Discrete Fourier transform (DFT). Computation of the DFT including FFT algorithms. Short-time Fourier analysis and relation to filter banks. Multirate techniques. Perfect reconstruction filter banks and their relation to wavelets.
A. V. Oppenheim, J. Ward
Textbooks (Fall 2016)

6.344 Digital Image Processing
______

Graduate (Spring)
Prereq: 6.003, 6.041B
Units: 3-0-9
______
Digital images as two-dimensional signals. Digital signal processing theories used for digital image processing, including one-dimensional and two-dimensional convolution, Fourier transform, discrete Fourier transform, and discrete cosine transform. Image processing basics. Image enhancement. Image restoration. Image coding and compression. Video processing including video coding and compression. Additional topics including digital high-definition television systems.
J. S. Lim

6.345[J] Automatic Speech Recognition
______

Graduate (Spring)
(Same subject asHST.728[J])
Prereq: 6.003, 6.041, or permission of instructor
Units: 3-1-8
URL: http://courses.csail.mit.edu/6.345/
______
Introduces the rapidly developing fields of automatic speech recognition and spoken language processing. Topics include acoustic theory of speech production and perception, acoustic-phonetics, signal representation, acoustic and language modeling, search, hidden Markov modeling, robustness, adaptation, discriminative and alternative approaches. Lectures interspersed with theory and applications. Assignments include problems, laboratory exercises, and a term project. 4 Engineering Design Points.
V. W. Zue, J. R. Glass

6.347, 6.348 Advanced Topics in Signals and Systems
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
6.348: URL: http://www.eecs.mit.edu/academics-admissions/academic-information/subject-updates-ft-2014
______
Advanced study of topics in signals and systems. Specific focus varies from year to year.
Consult Department

6.374 Analysis and Design of Digital Integrated Circuits
______

Graduate (Fall)
Prereq: 6.012, 6.004
Units: 3-3-6
Lecture: TR11-12.30 (34-302) Lab: TBA
______
Device and circuit level optimization of digital building blocks. MOS device models including Deep Sub-Micron effects. Circuit design styles for logic, arithmetic, and sequential blocks. Estimation and minimization of energy consumption. Interconnect models and parasitics, device sizing and logical effort, timing issues (clock skew and jitter), and active clock distribution techniques. Memory architectures, circuits (sense amplifiers), and devices. Testing of integrated circuits. Extensive custom and standard cell layout and simulation in design projects and software labs.
V. Sze, A. P. Chandrakasan
Textbooks (Fall 2016)

6.375 Complex Digital Systems Design
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.004
Units: 5-5-2
______
Introduction to the design and implementation of large-scale digital systems using hardware description languages and high-level synthesis tools in conjunction with standard commercial electronic design automation (EDA) tools. Emphasizes modular and robust designs, reusable modules, correctness by construction, architectural exploration, meeting area and timing constraints, and developing functional field-programmable gate array (FPGA) prototypes. Extensive use of CAD tools in weekly labs serve as preparation for a multi-person design project on multi-million gate FPGAs. Enrollment may be limited.
Arvind

Probabilistic Systems and Communication

6.431A Introduction to Probability I
(New)
______

Graduate (Fall, Spring); first half of term
(Subject meets with6.041A)
Prereq: Calculus II (GIR)
Units: 2-0-4
Ends Oct 21. Lecture: MW12 (34-101) Recitation: TR11 (24-121) or TR12 (24-121) or TR1 (24-121) or TR2 (24-121)
______
Provides an introduction to probability theory and the modeling and analysis of probabilistic systems. Probabilistic models, conditional probability. Discrete and continuous random variables. Expectation and conditional expectation. Limit Theorems. Students taking graduate version complete additional assignments.
P. Jaillet, J. N. Tsitsiklis
No textbook information available

6.431B Introduction to Probability II
(New)
______

Graduate (Fall, Spring); second half of term
(Subject meets with6.041B)
Prereq: 6.431A
Units: 2-0-4
Begins Oct 24. Lecture: MW12 (34-101) Recitation: TR11 (24-121) or TR12 (24-121) or TR1 (24-121) or TR2 (24-121) +final
______
Further topics in probability. Bayesian estimation and hypothesis testing. Elements of statistical inference. Bernoulli and Poisson processes. Markov chains. Students taking graduate version complete additional assignments.
P. Jaillet, J. N. Tsitsiklis
No textbook information available

6.434[J] Statistics for Engineers and Scientists
______

Graduate (Fall)
(Same subject as16.391[J])
Prereq: Calculus II (GIR), 18.06, 6.431B, or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (8-205)
______
Rigorous introduction to fundamentals of statistics motivated by engineering applications. Topics include exponential families, order statistics, sufficient statistics, estimation theory, hypothesis testing, measures of performance, notions of optimality, analysis of variance (ANOVA), simple linear regression, and selected topics.
M. Win, J. N. Tsitsiklis
No textbook information available

6.436[J] Fundamentals of Probability
______

Graduate (Fall)
(Same subject as15.085[J])
Prereq: Calculus II (GIR)
Units: 4-0-8
Lecture: MW2.30-4 (E51-345) Recitation: F2 (66-144) +final
______
Introduction to probability theory. Probability spaces and measures. Discrete and continuous random variables. Conditioning and independence. Multivariate normal distribution. Abstract integration, expectation, and related convergence results. Moment generating and characteristic functions. Bernoulli and Poisson process. Finite-state Markov chains. Convergence notions and their relations. Limit theorems. Familiarity with elementary notions in probability and real analysis is desirable.
J. N. Tsitsiklis, D. Gamarnik
Textbooks (Fall 2016)

6.437 Inference and Information
______

Graduate (Spring)
Prereq: 6.008, 6.041B, or 6.436
Units: 4-0-8
______
Introduction to principles of Bayesian and non-Bayesian statistical inference. Hypothesis testing and parameter estimation, sufficient statistics; exponential families. EM agorithm. Log-loss inference criterion, entropy and model capacity. Kullback-Leibler distance and information geometry. Asymptotic analysis and large deviations theory. Model order estimation; nonparametric statistics. Computational issues and approximation techniques; Monte Carlo methods. Selected special topics such as universal prediction and compression.
P. Golland, G. W. Wornell

6.438 Algorithms for Inference
______

Graduate (Fall)
Prereq: 6.008, 6.041B, or 6.436; 18.06
Units: 4-0-8
Lecture: TR9.30-11 (4-370) Recitation: F10 (8-119) or F11 (8-119) +final
______
Introduction to statistical inference with probabilistic graphical models. Directed and undirected graphical models, and factor graphs, over discrete and Gaussian distributions; hidden Markov models, linear dynamical systems. Sum-product and junction tree algorithms; forward-backward algorithm, Kalman filtering and smoothing. Min-sum and Viterbi algorithms. Variational methods, mean-field theory, and loopy belief propagation. Particle methods and filtering. Building graphical models from data, including parameter estimation and structure learning; Baum-Welch and Chow-Liu algorithms. Selected special topics.
P. Golland, G. W. Wornell, D. Shah
No textbook information available

6.440 Essential Coding Theory
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.006, 6.045
Units: 3-0-9
______
Introduces the theory of error-correcting codes. Focuses on the essential results in the area, taught from first principles. Special focus on results of asymptotic or algorithmic significance. Principal topics include construction and existence results for error-correcting codes; limitations on the combinatorial performance of error-correcting codes; decoding algorithms; and applications to other areas of mathematics and computer science.
Staff

6.441 Information Theory
______

Graduate (Spring)
Prereq: 6.041B
Units: 3-0-9
URL: http://web.mit.edu/6.441/www/
______
Mathematical definitions of information measures, convexity, continuity, and variational properties. Lossless source coding; variable-length and block compression; Slepian-Wolf theorem; ergodic sources and Shannon-McMillan theorem. Hypothesis testing, large deviations and I-projection. Fundamental limits of block coding for noisy channels: capacity, dispersion, finite blocklength bounds. Coding with feedback. Joint source-channel problem. Rate-distortion theory, vector quantizers. Advanced topics include Gelfand-Pinsker problem, multiple access channels, broadcast channels (depending on available time).
M. Medard, Y. Polyanskiy, L. Zheng

6.442 Optical Networks
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.041B or 6.042
Units: 3-0-9
______
Introduces the fundamental and practical aspects of optical network technology, architecture, design and analysis tools and techniques. The treatment of optical networks are from the architecture and system design points of view. Optical hardware technologies are introduced and characterized as fundamental network building blocks on which optical transmission systems and network architectures are based. Beyond the Physical Layer, the higher network layers (Media Access Control, Network and Transport Layers) are treated together as integral parts of network design. Performance metrics, analysis and optimization techniques are developed to help guide the creation of high performance complex optical networks.
V. W. S. Chan

6.443[J] Quantum Information Science
______

Graduate (Spring)
(Same subject as8.371[J],18.436[J])
Prereq: 18.435
Units: 3-0-9
______
Examines quantum computation and quantum information. Topics include quantum circuits, the quantum Fourier transform and search algorithms, the quantum operations formalism, quantum error correction, Calderbank-Shor-Steane and stabilizer codes, fault tolerant quantum computation, quantum data compression, quantum entanglement, capacity of quantum channels, and quantum cryptography and the proof of its security. Prior knowledge of quantum mechanics required.
I. Chuang

6.450 Principles of Digital Communication
______

Graduate (Fall)
Prereq: 6.011
Units: 3-0-9
Lecture: MW9.30-11 (36-155) +final
______
Communication sources and channels; data compression; entropy and the AEP; Lempel-Ziv universal coding; scalar and vector quantization; L2 waveforms; signal space and its representation by sampling and other expansions; aliasing; the Nyquist criterion; PAM and QAM modulation; Gaussian noise and random processes; detection and optimal receivers; fading channels and wireless communication; introduction to communication system design.
M. Medard, L. Zheng
Textbooks (Fall 2016)

6.452 Principles of Wireless Communication
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.450
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduction to design, analysis, and fundamental limits of wireless transmission systems. Wireless channel and system models; fading and diversity; resource management and power control; multiple-antenna and MIMO systems; space-time codes and decoding algorithms; multiple-access techniques and multiuser detection; broadcast codes and precoding; cellular and ad-hoc network topologies; OFDM and ultrawideband systems; architectural issues.
G. W. Wornell, L. Zheng

6.453 Quantum Optical Communication
______

Graduate (Fall)
Prereq: 6.011, 18.06
Units: 3-0-9
Lecture: TR1-2.30 (8-205)
______
Quantum optics: Dirac notation quantum mechanics; harmonic oscillator quantization; number states, coherent states, and squeezed states; radiation field quantization and quantum field propagation; P-representation and classical fields. Linear loss and linear amplification: commutator preservation and the Uncertainty Principle; beam splitters; phase-insensitive and phase-sensitive amplifiers. Quantum photodetection: direct detection, heterodyne detection, and homodyne detection. Second-order nonlinear optics: phasematched interactions; optical parametric amplifiers; generation of squeezed states, photon-twin beams, non-classical fourth-order interference, and polarization entanglement. Quantum systems theory: optimum binary detection; quantum precision measurements; quantum cryptography; and quantum teleportation.
J. H. Shapiro
No required or recommended textbooks

6.454 Graduate Seminar in Area I
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
URL: http://web.mit.edu/6.454/www/
______
Student-run advanced graduate seminar with focus on topics in communications, control, signal processing, optimization. Participants give presentations outside of their own research to expose colleagues to topics not covered in the usual curriculum. Recent topics have included compressed sensing, MDL principle, communication complexity, linear programming decoding, biology in EECS, distributed hypothesis testing, algorithms for random satisfaction problems, and cryptogaphy. Open to advanced students from all areas of EECS. Limited to 12.
L. Zheng, D. Shah

6.456 Array Processing
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.341; 2.687, or 6.011 and 18.06
Units: 3-2-7
Subject Cancelled Subject Cancelled
______
Adaptive and non-adaptive processing of signals received at arrays of sensors. Deterministic beamforming, space-time random processes, optimal and adaptive algorithms, and the sensitivity of algorithm performance to modeling errors and limited data. Methods of improving the robustness of algorithms to modeling errors and limited data are derived. Advanced topics include an introduction to matched field processing and physics-based methods of estimating signal statistics. Homework exercises providing the opportunity to implement and analyze the performance of algorithms in processing data supplied during the course.
Staff

Bioelectrical Engineering

6.503 Foundations of Algorithms and Computational Techniques in Systems Biology
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with6.581[J],20.482[J])
Prereq: 6.021, 6.034, 6.046, 6.336, 18.417, or permission of instructor
Units: 3-0-9
______
Illustrates computational approaches to solving problems in systems biology. Uses a series of case studies to demonstrate how an effective match between the statement of a biological problem and the selection of an appropriate algorithm or computational technique can lead to fundamental advances. Covers several discrete and numerical algorithms used in simulation, feature extraction, and optimization for molecular, network, and systems models in biology. Students taking graduate version complete additional assignments.
B. Tidor, J. K. White

6.521[J] Cellular Neurophysiology
______

Graduate (Fall)
(Same subject as2.794[J],20.470[J],HST.541[J])
(Subject meets with2.791[J],6.021[J],20.370[J])
Prereq: Physics II (GIR); 18.03; 2.005, 6.002, 6.003, 6.071, 10.301, 20.110, or permission of instructor
Units: 5-2-5
Lecture: MWF10 (32-144) Lab: TBA Recitation: T12 (34-303) or T4 (34-302) +final
______
Meets with undergraduate subject 6.021J. Requires the completion of more advanced home problems and/or an additional project.
J. Han, T. Heldt
Textbooks (Fall 2016)

6.522[J] Quantitative Physiology: Organ Transport Systems
______

Graduate (Spring)
(Same subject as2.796[J])
(Subject meets with2.792[J],6.022[J],HST.542[J])
Prereq: 2.006 or 6.013; 6.021
Units: 4-2-6
______
Application of the principles of energy and mass flow to major human organ systems. Mechanisms of regulation and homeostasis. Anatomical, physiological and pathophysiological features of the cardiovascular, respiratory and renal systems. Systems, features and devices that are most illuminated by the methods of physical sciences. Laboratory work includes some animal studies. Students taking graduate version complete additional assignments.
Application of the principles of energy and mass flow to major human organ systems. Mechanisms of regulation and homeostasis. Anatomical, physiological and pathophysiological features of the cardiovascular, respiratory and renal systems. Systems, features and devices that are most illuminated by the methods of physical sciences. Laboratory work includes some animal studies. Students taking graduate version complete additional assignments.
T. Heldt, R. G. Mark, C. M. Stultz

6.524[J] Molecular, Cellular, and Tissue Biomechanics
______

Graduate (Fall)
(Same subject as2.798[J],3.971[J],10.537[J],20.410[J])
Prereq: Biology (GIR); 2.002, 2.006, 6.013, 10.301, or 10.302
Units: 3-0-9
Lecture: TR10.30-12 (2-143)
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, K. J. Van Vliet
No textbook information available

6.525[J] Medical Device Design
______

Graduate (Fall)
(Same subject as2.75[J],HST.552[J])
(Subject meets with2.750[J],6.025[J])
Prereq: 2.72, 6.101, 6.111, 6.115, 22.071, or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (3-270)
______
Application of mechanical and electrical engineering fundamentals to the design of medical devices that address clinical needs. Students work in small teams on a major project to translate a clinical challenge into a proof-of-concept prototype device. Students conduct user analysis, develop design specifications, and follow a structured process to cultivate creative designs and apply analytical techniques to optimize them. They deepen their understanding of art and intellectual property by researching prior representations. Develops practical skills in prototyping and testing as well as project management. Includes lectures, problem sets and exams that focus on design fundamentals. Instruction and practice in written and oral communication provided. Students taking graduate version complete additional assignments. Enrollment limited.
A. H. Slocum, G. Hom
No required or recommended textbooks

6.542[J] Laboratory on the Physiology, Acoustics, and Perception of Speech
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as24.966[J],HST.712[J])
Prereq: Permission of instructor
Units: 2-2-8
______
Experimental investigations of speech processes. Topics: measurement of articulatory movements; measurements of pressures and airflows in speech production; computer-aided waveform analysis and spectral analysis of speech; synthesis of speech; perception and discrimination of speechlike sounds; speech prosody; models for speech recognition; speech development; and other topics. Recommended prerequisites: 6.002 or 18.03.
L. D. Braida, S. Shattuck-Hufnagel

6.544, 6.545 Advanced Topics in BioEECS
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Advanced study of topics in BioEECS. Specific focus varies from year to year. Consult department for details.
Consult Department

6.552[J] Signal Processing by the Auditory System: Perception
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject asHST.716[J])
Prereq: 6.003; 6.041B or 6.431B; or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Studies information processing performance of the human auditory system in relation to current physiological knowledge. Examines mathematical models for the quantification of auditory-based behavior and the relation between behavior and peripheral physiology, reflecting the tono-topic organization and stochastic responses of the auditory system. Mathematical models of psychophysical relations, incorporating quantitative knowledge of physiological transformations by the peripheral auditory system.
L. D. Braida

6.555[J] Biomedical Signal and Image Processing
______

Graduate (Spring)
(Same subject as16.456[J],HST.582[J])
Prereq: 6.003, 2.004, 16.004, or 18.085
Units: 3-4-5
URL: http://web.mit.edu/6.555/www/
______
Fundamentals of digital signal processing with particular emphasis on problems in biomedical research and clinical medicine. Basic principles and algorithms for data acquisition, imaging, filtering, and feature extraction. Laboratory projects provide practical experience in processing physiological data, with examples from cardiology, speech processing, and medical imaging.
J. Greenberg, E. Adalsteinsson, W. Wells

6.556[J] Data Acquisition and Image Reconstruction in MRI
______

Graduate (Fall)
(Same subject asHST.580[J])
Prereq: 6.011
Units: 3-0-9
Lecture: TR11-12.30 (1-150)
______
Applies analysis of signals and noise in linear systems, sampling, and Fourier properties to magnetic resonance (MR) imaging acquisition and reconstruction. Provides adequate foundation for MR physics to enable study of RF excitation design, efficient Fourier sampling, parallel encoding, reconstruction of non-uniformly sampled data, and the impact of hardware imperfections on reconstruction performance. Surveys active areas of MR research. Assignments include Matlab-based work with real data. Includes visit to a scan site for human MR studies.
E. Adalsteinsson
No textbook information available

6.557[J] Biomolecular Feedback Systems
______

Graduate (Spring)
(Same subject as2.18[J])
(Subject meets with2.180[J],6.027[J])
Prereq: 18.03, Biology (GIR), or permission of instructor
Units: 3-0-9
______
Comprehensive introduction to dynamics and control of biomolecular systems with emphasis on design/analysis techniques from control theory. Provides a review of biology concepts, regulation mechanisms, and models. Covers basic enabling technologies, engineering principles for designing biological functions, modular design techniques, and design limitations. Students taking graduate version complete additional assignments.
D. Del Vecchio, R. Weiss

6.561[J] Fields, Forces, and Flows in Biological Systems
______

Graduate (Fall)
(Same subject as2.795[J],10.539[J],20.430[J])
Prereq: 6.013, 2.005, 10.302, or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (32-124)
______
Molecular diffusion, diffusion-reaction, conduction, convection in biological systems; fields in heterogeneous media; electrical double layers; Maxwell stress tensor, electrical forces in physiological systems. Fluid and solid continua: equations of motion useful for porous, hydrated biological tissues. Case studies of membrane transport, electrode interfaces, electrical, mechanical, and chemical transduction in tissues, convective-diffusion/reaction, electrophoretic, electroosmotic flows in tissues/MEMs, and ECG. Electromechanical and physicochemical interactions in cells and biomaterials; musculoskeletal, cardiovascular, and other biological and clinical examples.
M. Bathe, A. J. Grodzinsky
Textbooks (Fall 2016)

6.580[J] Principles of Synthetic Biology
______

Undergrad (Fall)
(Same subject as20.305[J])
(Subject meets with6.589[J],20.405[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (9-057) +final
______
Introduces the basics of synthetic biology, including quantitative cellular network characterization and modeling. Considers the discovery and genetic factoring of useful cellular activities into reusable functions for design. Emphasizes the principles of biomolecular system design and diagnosis of designed systems. Illustrates cutting-edge applications in synthetic biology and enhances skills in analysis and design of synthetic biological applications. Students taking graduate version complete additional assignments.
R. Weiss
No textbook information available

6.581[J] Foundations of Algorithms and Computational Techniques in Systems Biology
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as20.482[J])
(Subject meets with6.503)
Prereq: 6.021, 6.034, 6.046, 6.336, 18.417, or permission of instructor
Units: 3-0-9
______
Illustrates computational approaches to solving problems in systems biology. Uses a series of case studies to demonstrate how an effective match between the statement of a biological problem and the selection of an appropriate algorithm or computational technique can lead to fundamental advances. Covers several discrete and numerical algorithms used in simulation, feature extraction, and optimization for molecular, network, and systems models in biology. Students taking graduate version complete additional assignments.
B. Tidor, J. K. White

6.589[J] Principles of Synthetic Biology
______

Graduate (Fall)
(Same subject as20.405[J])
(Subject meets with6.580[J],20.305[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (9-057) +final
______
Introduces the basics of synthetic biology, including quantitative cellular network characterization and modeling. Considers the discovery and genetic factoring of useful cellular activities into reusable functions for design. Emphasizes the principles of biomolecular system design and diagnosis of designed systems. Illustrates cutting-edge applications in synthetic biology and enhances skills in analysis and design of synthetic biological applications. Students taking graduate version complete additional assignments.
R. Weiss
No textbook information available

Electrodynamics

6.602 Fundamentals of Photonics
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with6.621)
Prereq: 2.71, 6.013, or 8.07
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Covers the fundamentals of optics and the interaction of light and matter, leading to devices such as light emitting diodes, optical amplifiers, and lasers. Topics include classical ray, wave, beam, and Fourier optics; Maxwell's electromagnetic waves; resonators; quantum theory of photons; light-matter interaction; laser amplification; lasers; and semiconductors optoelectronics. Students taking graduate version complete additional assignments.
D. R. Englund

6.621 Fundamentals of Photonics
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with6.602)
Prereq: 2.71, 6.013, or 8.07
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Covers the fundamentals of optics and the interaction of light and matter, leading to devices such as light emitting diodes, optical amplifiers, and lasers. Topics include classical ray, wave, beam, and Fourier optics; Maxwell's electromagnetic waves; resonators; quantum theory of photons; light-matter interaction; laser amplification; lasers; and semiconductors optoelectronics. Students taking graduate version complete additional assignments.
D. R. Englund

6.630 Electromagnetics
______

Graduate (Fall)
Prereq: 6.003 or 6.007
Units: 4-0-8
URL: http://cetaweb.mit.edu/6.630/
Lecture: WF2.30-4 (32-144)
______
Explores electromagnetic phenomena in modern applications, including wireless and optical communications, circuits, computer interconnects and peripherals, microwave communications and radar, antennas, sensors, micro-electromechanical systems, and power generation and transmission. Fundamentals include quasistatic and dynamic solutions to Maxwell's equations; waves, radiation, and diffraction; coupling to media and structures; guided and unguided waves; modal expansions; resonance; acoustic analogs; and forces, power, and energy.
L. Daniel, M. R. Watts
Textbooks (Fall 2016)

6.631 Optics and Photonics
______

Graduate (Fall)
Prereq: 6.013 or 8.07
Units: 3-0-9
Lecture: MW3-4.30 (36-372) +final
______
Introduction to fundamental concepts and techniques of optics, photonics, and fiber optics. Review of Maxwell's equations, light propagation, and reflection from dielectrics mirrors and filters. Interferometers, filters, and optical imaging systems. Fresnel and Fraunhoffer diffraction theory. Propagation of Gaussian beams and laser resonator design. Optical waveguides and optical fibers. Optical waveguide and photonic devices.
J. G. Fujimoto
Textbooks (Fall 2016)

6.632 Electromagnetic Wave Theory
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.013, 6.630, or 8.07
Units: 3-0-9
______
Solutions to Maxwell equations and physical interpretation. Topics include waves in media, equivalence principle, duality and complementarity, Huygens' principle, Fresnel and Fraunhofer diffraction, radiation and dyadic Green's functions, scattering, metamaterials, and plasmonics, mode theory, dielectric waveguides, and resonators. Examples deal with limiting cases of electromagnetic theory, multi-port elements, filters and antennas. Discusses current topics in microwave and photonic devices.
M. R. Watts

6.634[J] Nonlinear Optics
______

Graduate (Spring)
(Same subject as8.431[J])
Prereq: 6.013 or 8.07
Units: 3-0-9
______
Techniques of nonlinear optics with emphasis on fundamentals for research and engineering in optics, photonics, and spectroscopy. Electro optic modulators, harmonic generation, and frequency conversion devices. Nonlinear effects in optical fibers including self-phase modulation, nonlinear wave propagation, and solitons. Interaction of light with matter, laser operation, density matrix techniques, nonlinear spectroscopies, and femtosecond optics.
J. G. Fujimoto

6.637 Optical Signals, Devices, and Systems
______

Graduate (Fall)
(Subject meets with6.161)
Prereq: 6.003
Units: 3-0-9
Lecture: TR2.30-4 (34-304) Lab: TBA
______
Principles of operation and applications of devices and systems for optical signal generation, transmission, detection, storage, processing and display. Topics include review of the basic properties of electromagnetic waves; coherence and interference; diffraction and holography; Fourier optics; coherent and incoherent imaging and signal processing systems; optical properties of materials; lasers and LEDs; electro-optic and acousto-optic light modulators; photorefractive and liquid-crystal light modulation; spatial light modulators and displays; optical waveguides and fiber-optic communication systems; photodetectors; 2-D and 3-D optical storage technologies; adaptive optical systems; role of optics in next-generation computers. Student research paper on a specific contemporary topic required. Recommended prerequisites: 6.007 or 8.03.
C. Warde
No textbook information available

6.641 Electromagnetic Fields, Forces, and Motion
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.013
Units: 4-0-8
______
Electric and magnetic quasistatic forms of Maxwell's equations applied to dielectric, conduction, and magnetization boundary value problems. Electromagnetic forces, force densities, and stress tensors, including magnetization and polarization. Thermodynamics of electromagnetic fields, equations of motion, and energy conservation. Applications to synchronous, induction, and commutator machines; sensors and transducers; microelectromechanical systems; propagation and stability of electromechanical waves; and charge transport phenomena.
J. H. Lang

6.642 Continuum Electromechanics
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.641 or permission of instructor
Units: 4-0-8
______
Laws, approximations, and relations of continuum mechanics. Mechanical and electromechanical transfer relations. Statics and dynamics of electromechanical systems having a static equilibrium. Electromechanical flows. Field coupling with thermal and molecular diffusion. Electrokinetics. Streaming interactions. Application to materials processing, magnetohydrodynamic and electrohydrodynamic pumps and generators, ferrohydrodynamics, physiochemical systems, heat transfer, continuum feedback control, electron beam devices, and plasma dynamics.
Staff

6.644, 6.645 Advanced Topics in Applied Physics
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled 6.645 Cancelled
______
Advanced study of topics in applied physics. Specific focus varies from year to year. Consult department for details.
Consult Department

6.685 Electric Machines
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.061 or 6.690; or permission of instructor
Units: 3-0-9
______
Treatment of electromechanical transducers, rotating and linear electric machines. Lumped-parameter electromechanics. Power flow using Poynting's theorem, force estimation using the Maxwell stress tensor and Principle of virtual work. Development of analytical techniques for predicting device characteristics: energy conversion density, efficiency; and of system interaction characteristics: regulation, stability, controllability, and response. Use of electric machines in drive systems. Problems taken from current research.
J. L. Kirtley, Jr.

6.690 Introduction to Electric Power Systems
______

Not offered academic year 2017-2018Graduate (Spring)
(Subject meets with6.061)
Prereq: 6.002, 6.013
Units: 3-0-9
______
Electric circuit theory with application to power handling electric circuits. Modeling and behavior of electromechanical devices, including magnetic circuits, motors, and generators. Operational fundamentals of synchronous, induction and DC machinery. Interconnection of generators and motors with electric power transmission and distribution circuits. Power generation, including alternative and sustainable sources. Students taking graduate version complete additional assignments.
J. L. Kirtley, Jr.

6.695[J] Engineering, Economics and Regulation of the Electric Power Sector
______

Graduate (Spring)
(Same subject as15.032[J],IDS.505[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Provides an in-depth and interdisciplinary look at electric power systems, focusing on regulation as the link among engineering, economic, legal, and environmental viewpoints. Topics include electricity markets, incentive regulation of network utilities, retail competition, tariff design, distributed generation, rural electrification, multinational electricity markets, environmental impacts, future of utilities and strategic sustainability issues under both traditional and competitive regulatory frameworks. Background in policy, microeconomics, or engineering desirable.
C. Vergara

Solid-State Materials and Devices

6.701 Introduction to Nanoelectronics
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with6.719)
Prereq: 6.003
Units: 4-0-8
Subject Cancelled Subject Cancelled
______
Transistors at the nanoscale. Quantization, wavefunctions, and Schrodinger's equation. Introduction to electronic properties of molecules, carbon nanotubes, and crystals. Energy band formation and the origin of metals, insulators and semiconductors. Ballistic transport, Ohm's law, ballistic versus traditional MOSFETs, fundamental limits to computation.
M. A. Baldo

6.717[J] Design and Fabrication of Microelectromechanical Systems
______

Not offered academic year 2016-2017Undergrad (Spring)
(Same subject as2.374[J])
(Subject meets with2.372[J],6.777[J])
Prereq: 6.003 or 2.003, Physics II (GIR); or permission of instructor
Units: 3-0-9
______
Provides an introduction to microsystem design. Covers material properties, microfabrication technologies, structural behavior, sensing methods, electromechanical actuation, thermal actuation and control, multi-domain modeling, noise, and microsystem packaging. Applies microsystem modeling, and manufacturing principles to the design and analysis a variety of microscale sensors and actuators (e.g., optical MEMS, bioMEMS, and inertial sensors). Emphasizes modeling and simulation in the design process. Students taking the graduate version complete additional assignments.
Staff

6.719 Nanoelectronics
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with6.701)
Prereq: 6.003
Units: 4-0-8
Subject Cancelled Subject Cancelled
______
Meets with undergraduate subject 6.701, but requires the completion of additional/different homework assignments and or projects. See subject description under 6.701.
M. A. Baldo

6.720[J] Integrated Microelectronic Devices
______

Graduate (Fall)
(Same subject as3.43[J])
Prereq: 6.012 or 3.42
Units: 4-0-8
Lecture: MWRF10 (66-144) +final
______
Covers physics of microelectronic semiconductor devices for integrated circuit applications. Topics include semiconductor fundamentals, p-n junction, metal-oxide semiconductor structure, metal-semiconductor junction, MOS field-effect transistor, and bipolar junction transistor. Studies modern nanoscale devices, including electrostatic scaling, materials beyond Si, carrier transport from the diffusive to the ballistic regime. Emphasizes physical understanding of device operation through energy band diagrams and short-channel MOSFET device design. Includes device modeling exercises. Familiarity with MATLAB required. 2 Engineering Design Points.
D. A. Antoniadis, J. A. del Alamo, H. L. Tuller
No textbook information available

6.728 Applied Quantum and Statistical Physics
______

Graduate (Fall)
Prereq: 6.003, 18.06
Units: 4-0-8
Lecture: WF11-12.30 (26-328) Recitation: M11 (26-328) +final
______
Elementary quantum mechanics and statistical physics. Introduces applied quantum physics. Emphasizes experimental basis for quantum mechanics. Applies Schrodinger's equation to the free particle, tunneling, the harmonic oscillator, and hydrogen atom. Variational methods. Elementary statistical physics; Fermi-Dirac, Bose-Einstein, and Boltzmann distribution functions. Simple models for metals, semiconductors, and devices such as electron microscopes, scanning tunneling microscope, thermonic emitters, atomic force microscope, and more.
P. L. Hagelstein
Textbooks (Fall 2016)

6.730 Physics for Solid-State Applications
______

Graduate (Spring)
Prereq: 6.013, 6.728
Units: 5-0-7
______
Classical and quantum models of electrons and lattice vibrations in solids, emphasizing physical models for elastic properties, electronic transport, and heat capacity. Crystal lattices, electronic energy band structures, phonon dispersion relations, effective mass theorem, semiclassical equations of motion, electron scattering and semiconductor optical properties. Band structure and transport properties of selected semiconductors. Connection of quantum theory of solids with quasi-Fermi levels and Boltzmann transport used in device modeling.
Q. Hu, R. Ram

6.731 Semiconductor Optoelectronics: Theory and Design
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 6.728, 6.012
Units: 3-0-9
______
Focuses on the physics of the interaction of photons with semiconductor materials. Uses the band theory of solids to calculate the absorption and gain of semiconductor media; and uses rate equation formalism to develop the concepts of laser threshold, population inversion, and modulation response. Presents theory and design for photodetectors, solar cells, modulators, amplifiers, and lasers. Introduces noise models for semiconductor devices, and applications of optoelectronic devices to fiber optic communications.
R. J. Ram

6.732 Physics of Solids
______

Graduate (Fall)
Prereq: 6.730 or 8.231
Units: 4-0-8
Lecture: MWF11 (34-303) Recitation: F10 (34-303)
______
Continuation of 6.730 emphasizing applications-related physical issues in solids. Topics include: electronic structure and energy band diagrams of semiconductors, metals, and insulators; Fermi surfaces; dynamics of electrons under electric and magnetic fields; classical diffusive transport phenomena such as electrical and thermal conduction and thermoelectric phenomena; quantum transport in tunneling and ballistic devices; optical properties of metals, semiconductors, and insulators; impurities and excitons; photon-lattice interactions; Kramers-Kronig relations; optoelectronic devices based on interband and intersubband transitions; magnetic properties of solids; exchange energy and magnetic ordering; magneto-oscillatory phenomena; quantum Hall effect; superconducting phenomena and simple models.
Q. Hu
No textbook information available

6.735, 6.736 Advanced Topics in Materials, Devices, and Nanotechnology
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Advanced study of topics in materials, devices, and nanotechnology. Specific focus varies from year to year.
Consult Department

6.774 Physics of Microfabrication: Front End Processing
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 6.152
Units: 3-0-9
______
Presents advanced physical models and practical aspects of front-end microfabrication processes, such as oxidation, diffusion, ion implantation, chemical vapor deposition, atomic layer deposition, etching, and epitaxy. Covers topics relevant to CMOS, bipolar, and optoelectronic device fabrication, including high k gate dielectrics, gate etching, implant-damage enhanced diffusion, advanced metrology, stress effects on oxidation, non-planar and nanowire device fabrication, SiGe and fabrication of process-induced strained Si. Exposure to CMOS process integration concepts, and impacts of processing on device characteristics. Students use modern process simulation tools.
J. L. Hoyt, L. R. Reif

6.775 CMOS Analog and Mixed-Signal Circuit Design
______

Graduate (Spring)
Prereq: 6.301
Units: 3-0-9
______
A detailed exposition of the principles involved in designing and optimizing analog and mixed-signal circuits in CMOS technologies. Small-signal and large-signal models. Systemic methodology for device sizing and biasing. Basic circuit building blocks. Operational amplifier design. Large signal considerations. Principles of switched capacitor networks including switched-capacitor and continuous-time integrated filters. Basic and advanced A/D and D/A converters, delta-sigma modulators, RF and other signal processing circuits. Design projects on op amps and subsystems are a required part of the subject. 4 Engineering Design Points.
H. S. Lee

6.776 High Speed Communication Circuits
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.301
Units: 3-3-6
______
Principles and techniques of high-speed integrated circuits used in wireless/wireline data links and remote sensing. On-chip passive component design of inductors, capacitors, and antennas. Analysis of distributed effects, such as transmission line modeling, S-parameters, and Smith chart. Transceiver architectures and circuit blocks, which include low-noise amplifiers, mixers, voltage-controlled oscillators, power amplifiers, and frequency dividers. Involves IC/EM simulation and laboratory projects.
R. Han

6.777[J] Design and Fabrication of Microelectromechanical Systems
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as2.372[J])
(Subject meets with2.374[J],6.717[J])
Prereq: 6.003 or 2.003, Physics II (GIR); or permission of instructor
Units: 3-0-9
______
Provides an introduction to microsystem design. Covers material properties, microfabrication technologies, structural behavior, sensing methods, electromechanical actuation, thermal actuation and control, multi-domain modeling, noise, and microsystem packaging. Applies microsystem modeling, and manufacturing principles to the design and analysis a variety of microscale sensors and actuators (e.g., optical MEMS, bioMEMS, and inertial sensors). Emphasizes modeling and simulation in the design process. Students taking the graduate version complete additional assignments. 4 Engineering Design Points.
Staff

6.780[J] Control of Manufacturing Processes
______

Graduate (Spring)
(Same subject as2.830[J])
Prereq: 2.008, 6.041B, 6.152, or 15.064
Units: 3-0-9
______
Statistical modeling and control in manufacturing processes. Use of experimental design and response surface modeling to understand manufacturing process physics. Defect and parametric yield modeling and optimization. Forms of process control, including statistical process control, run by run and adaptive control, and real-time feedback control. Application contexts include semiconductor manufacturing, conventional metal and polymer processing, and emerging micro-nano manufacturing processes.
D. E. Hardt, D. S. Boning

6.781[J] Nanostructure Fabrication
______

Graduate (Spring)
(Same subject as2.391[J])
Prereq: 6.152, 6.161, or 2.710; or permission of instructor
Units: 4-0-8
______
Describes current techniques used to analyze and fabricate nanometer-length-scale structures and devices. Emphasizes imaging and patterning of nanostructures, including fundamentals of optical, electron (scanning, transmission, and tunneling), and atomic-force microscopy; optical, electron, ion, and nanoimprint lithography, templated self-assembly, and resist technology. Surveys substrate characterization and preparation, facilities, and metrology requirements for nanolithography. Addresses nanodevice processing methods, such as liquid and plasma etching, lift-off, electroplating, and ion-implant. Discusses applications in nanoelectronics, nanomaterials, and nanophotonics.
K. K. Berggren


left arrow|6.00-6.299|6.30-6.799|6.80-6.ZZZ|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 6: Electrical Engineering and Computer Science
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Course 6: Electrical Engineering and Computer Science
Fall 2016


Computer Science

6.801 Machine Vision
______

Not offered academic year 2017-2018Undergrad (Fall)
(Subject meets with6.866)
Prereq: 6.003 or permission of instructor
Units: 3-0-9
Lecture: TR9.30-11 (32-124)
______
Deriving a symbolic description of the environment from an image. Understanding physics of image formation. Image analysis as an inversion problem. Binary image processing and filtering of images as preprocessing steps. Recovering shape, lightness, orientation, and motion. Using constraints to reduce the ambiguity. Photometric stereo and extended Gaussian sphere. Applications to robotics; intelligent interaction of machines with their environment. Students taking the graduate version complete different assignments.
B. K. P. Horn
Textbooks (Fall 2016)

6.802[J] Foundations of Computational and Systems Biology
______

Undergrad (Spring)
(Same subject as20.390[J])
(Subject meets with6.874[J],20.490,HST.506[J])
Prereq: Biology (GIR), 6.0002 or 6.01; 7.05; or permission of instructor
Units: 3-0-9
______
Provides an introduction to computational and systems biology. Includes units on the analysis of protein and nucleic acid sequences, protein structures, and biological networks. Presents principles and methods used for sequence alignment, motif finding, expression array analysis, structural modeling, structure design and prediction, and network analysis and modeling. Techniques include dynamic programming, Markov and hidden Markov models, Bayesian networks, clustering methods, and energy minimization approaches. Exposes students to emerging research areas. Designed for students with strong backgrounds in either molecular biology or computer science. Some foundational material covering basic programming skills, probability and statistics is provided for students with less quantitative backgrounds. Students taking graduate version complete additional assignments.
D. K. Gifford, T. S. Jaakkola

6.803 The Human Intelligence Enterprise
______

Undergrad (Spring)
(Subject meets with6.833)
Prereq: 6.034 or permission of instructor
Units: 3-0-9
______
Analyzes seminal work directed at the development of a computational understanding of human intelligence, such as work on learning, language, vision, event representation, commonsense reasoning, self reflection, story understanding, and analogy. Reviews visionary ideas of Turing, Minsky, and other influential thinkers. Examines the implications of work on brain scanning, developmental psychology, and cognitive psychology. Emphasis on discussion and analysis of original papers. Students taking graduate version complete additional assignments. Enrollment limited.
P. H. Winston

6.804[J] Computational Cognitive Science
______

Undergrad (Fall)
(Same subject as9.66[J])
(Subject meets with9.660)
Prereq: 6.008, 6.036, 6.041B, 9.40, 18.05, or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (46-3189)
______
Introduction to computational theories of human cognition. Focus on principles of inductive learning and inference, and the representation of knowledge. Computational frameworks covered include Bayesian and hierarchical Bayesian models; probabilistic graphical models; nonparametric statistical models and the Bayesian Occam's razor; sampling algorithms for approximate learning and inference; and probabilistic models defined over structured representations such as first-order logic, grammars, or relational schemas. Applications to understanding core aspects of cognition, such as concept learning and categorization, causal reasoning, theory formation, language acquisition, and social inference. Graduate students complete a final project.
J. Tenenbaum
No required or recommended textbooks

6.805[J] Foundations of Information Policy
______

Undergrad (Fall) HASS Social Sciences
(Same subject asSTS.085[J])
(Subject meets withSTS.487)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: R1-4 (66-168)
______
Studies the growth of computer and communications technology and the new legal and ethical challenges that reflect tensions between individual rights and societal needs. Topics include computer crime; intellectual property restrictions on software; encryption, privacy, and national security; academic freedom and free speech. Students meet and question technologists, activists, law enforcement agents, journalists, and legal experts. Instruction and practice in oral and written communication provided. Students taking graduate version complete additional assignments. Enrollment limited.
H. Abelson, M. Fischer, D. Weitzner
No required or recommended textbooks

6.806 Advanced Natural Language Processing
______

Undergrad (Fall)
(Subject meets with6.864)
Prereq: 6.046 or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (32-123)
______
Introduces the study of human language from a computational perspective, including syntactic, semantic and discourse processing models. Emphasizes machine learning methods and algorithms. Uses these methods and models in applications such as syntactic parsing, information extraction, statistical machine translation, dialogue systems, and summarization. Students taking graduate version complete additional assignments.
R. A. Barzilay
No textbook information available

6.807 Computational Fabrication
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 6.837 or permission of instructor
Units: 3-0-9
______
Introduces computational aspects of computer-aided design and manufacturing. Explores relevant methods in the context of additive manufacturing (e.g., 3D printing). Topics include computer graphics (geometry modeling, solid modeling, procedural modeling), physically-based simulation (kinematics, finite element method), 3D scanning/geometry processing, and an overview of 3D fabrication methods. Exposes students to the latest research in computational fabrication.
W. Matusik

6.809[J] Interactive Music Systems
(New)
______

Undergrad (Fall, Spring) HASS Arts
(Same subject as21M.385[J])
(Subject meets with21M.585)
Prereq: 21M.301, 6.01; or permission of instructor
Units: 3-0-9
Lecture: MW11-12.30 (24-033F)
______
Explores audio synthesis, musical structure, human computer interaction (HCI), and visual presentation for the creation of interactive musical experiences. Topics include audio synthesis; mixing and looping; MIDI sequencing; generative composition; motion sensors; music games; and graphics for UI, visualization, and aesthetics. Includes weekly programming assignments in python. Teams build an original, dynamic, and engaging interactive music system for their final project. Limited to 18.
E. Egozy, L. Kaelbling
Textbooks (Fall 2016)

6.811[J] Principles and Practice of Assistive Technology
______

Undergrad (Fall)
(Same subject as2.78[J],HST.420[J])
Prereq: Permission of instructor
Units: 2-4-6
Lecture: M2 (32-144) Lab: W2-5 (32-044)
______
Students work closely with people with disabilities to develop assistive and adaptive technologies that help them live more independently. Covers design methods and problem-solving strategies; human factors; human-machine interfaces; community perspectives; social and ethical aspects; and assistive technology for motor, cognitive, perceptual, and age-related impairments. Prior knowledge of one or more of the following areas useful: software; electronics; human-computer interaction; cognitive science; mechanical engineering; control; or MIT hobby shop, MIT PSC, or other relevant independent project experience.
R. C. Miller, J. E. Greenberg, J. J. Leonard
Textbooks (Fall 2016)

6.813 User Interface Design and Implementation
______

Undergrad (Spring)
(Subject meets with6.831)
Prereq: 6.005, 6.031, or permission of instructor
Units: 4-0-8
______
Examines human-computer interaction in the context of graphical user interfaces. Covers human capabilities, design principles, prototyping techniques, evaluation techniques, and the implementation of graphical user interfaces. Includes short programming assignments and a semester-long group project. Students taking the graduate version also have readings from current literature and additional assignments. Enrollment limited.
R. C. Miller

6.814 Database Systems
______

Undergrad (Fall)
(Subject meets with6.830)
Prereq: 6.033; 6.046 or 6.006; or permission of instructor
Units: 3-0-9
Lecture: MW2.30-4 (32-155)
______
Topics related to the engineering and design of database systems, including data models; database and schema design; schema normalization and integrity constraints; query processing; query optimization and cost estimation; transactions; recovery; concurrency control; isolation and consistency; distributed, parallel and heterogeneous databases; adaptive databases; trigger systems; pub-sub systems; semi structured data and XML querying. Lecture and readings from original research papers. Semester-long project and paper. Students taking graduate version complete different assignments. Enrollment may be limited.
S. R. Madden
No textbook information available

6.815 Digital and Computational Photography
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with6.865)
Prereq: Calculus II (GIR), 6.005 or 6.031
Units: 3-0-9
______
Presents fundamentals and applications of hardware and software techniques used in digital and computational photography, with an emphasis on software methods. Provides sufficient background to implement solutions to photographic challenges and opportunities. Topics include cameras and image formation, image processing and image representations, high-dynamic-range imaging, human visual perception and color, single view 3-D model reconstruction, morphing, data-rich photography, super-resolution, and image-based rendering. Students taking graduate version complete additional assignments.
F. P. Durand

6.816 Multicore Programming
______

Undergrad (Spring)
(Subject meets with6.836)
Prereq: 6.006
Units: 4-0-8
______
Introduces principles and core techniques for programming multicore machines. Topics include locking, scalability, concurrent data structures, multiprocessor scheduling, load balancing, and state-of-the-art synchronization techniques, such as transactional memory. Includes sequence of programming assignments on a large multicore machine, culminating with the design of a highly concurrent application. Students taking graduate version complete additional assignments.
N. Shavit

6.819 Advances in Computer Vision
______

Undergrad (Fall)
(Subject meets with6.869)
Prereq: 6.041B or 6.042; 18.06
Units: 3-0-9
Lecture: TR9.30-11 (34-101)
______
Advanced topics in computer vision with a focus on the use of machine learning techniques and applications in graphics and human-computer interface. Covers image representations, texture models, structure-from-motion algorithms, Bayesian techniques, object and scene recognition, tracking, shape modeling, and image databases. Applications may include face recognition, multimodal interaction, interactive systems, cinematic special effects, and photorealistic rendering. Covers topics complementary to 6.801. Students taking graduate version complete additional assignments.
W. T. Freeman, A. Torralba
No textbook information available

6.820 Foundations of Program Analysis
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.035
Units: 3-0-9
______
Presents major principles and techniques for program analysis. Includes formal semantics, type systems and type-based program analysis, abstract interpretation and model checking and synthesis. Emphasis on Haskell and Ocaml, but no prior experience in these languages is assumed. Student assignments include implementing of techniques covered in class, including building simple verifiers.
A. Solar-Lezama

6.823 Computer System Architecture
______

Graduate (Spring)
Prereq: 6.004
Units: 4-0-8
______
Introduction to the principles underlying modern computer architecture. Emphasizes the relationship among technology, hardware organization, and programming systems in the evolution of computer architecture. Topics include pipelined, out-of-order, and speculative execution; caches, virtual memory and exception handling, superscalar, very long instruction word (VLIW), vector, and multithreaded processors; on-chip networks, memory models, synchronization, and cache coherence protocols for multiprocessors.
Arvind, J. S. Emer, D. Sanchez

6.824 Distributed Computer Systems Engineering
______

Graduate (Spring)
Prereq: 6.033, permission of instructor
Units: 3-0-9
______
Abstractions and implementation techniques for engineering distributed systems: remote procedure call, threads and locking, client/server, peer-to-peer, consistency, fault tolerance, and security. Readings from current literature. Individual laboratory assignments culminate in the construction of a fault-tolerant and scalable network file system. Programming experience with C/C++ required. Enrollment limited.
R. T. Morris, M. F. Kaashoek

6.828 Operating System Engineering
______

Graduate (Fall)
Prereq: 6.005 or 6.031, 6.033
Units: 3-6-3
Lecture: MW1-2.30 (1-190) +final
______
Fundamental design and implementation issues in the engineering of operating systems. Lectures based on the study of a symmetric multiprocessor version of UNIX version 6 and research papers. Topics include virtual memory; file system; threads; context switches; kernels; interrupts; system calls; interprocess communication; coordination, and interaction between software and hardware. Individual laboratory assignments accumulate in the construction of a minimal operating system (for an x86-based personal computer) that implements the basic operating system abstractions and a shell. Knowledge of programming in the C language is a prerequisite.
M. F. Kaashoek
No textbook information available

6.829 Computer Networks
______

Graduate (Fall)
Prereq: 6.033 or permission of instructor
Units: 4-0-8
URL: http://mit.edu/6.829
Lecture: TR1-2.30 (32-144)
______
Topics on the engineering and analysis of network protocols and architecture, including architectural principles for designing heterogeneous networks; transport protocols; Internet routing; router design; congestion control and network resource management; wireless networks; network security; naming; overlay and peer-to-peer networks. Readings from original research papers. Semester-long project and paper.
H. Balakrishnan, D. Katabi
No textbook information available

6.830 Database Systems
______

Graduate (Fall)
(Subject meets with6.814)
Prereq: 6.033; 6.046 or 6.006; or permission of instructor
Units: 3-0-9
Lecture: MW2.30-4 (32-155)
______
Topics related to the engineering and design of database systems, including data models; database and schema design; schema normalization and integrity constraints; query processing; query optimization and cost estimation; transactions; recovery; concurrency control; isolation and consistency; distributed, parallel and heterogeneous databases; adaptive databases; trigger systems; pub-sub systems; semi structured data and XML querying. Lecture and readings from original research papers. Semester-long project and paper. Students taking graduate version complete different assignments. Enrollment may be limited.
S. R. Madden
No textbook information available

6.831 User Interface Design and Implementation
______

Graduate (Spring)
(Subject meets with6.813)
Prereq: 6.005, 6.031, or permission of instructor
Units: 4-0-8
URL: http://groups.csail.mit.edu/uid/6.831/
______
Examines human-computer interaction in the context of graphical user interfaces. Covers human capabilities, design principles, prototyping techniques, evaluation techniques, and the implementation of graphical user interfaces. Includes short programming assignments and a semester-long group project. Students taking the graduate version also have readings from current literature and additional assignments. Enrollment limited.
R. C. Miller

6.832 Underactuated Robotics
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.141, 2.12, 2.165, or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Covers nonlinear dynamics and control of underactuated mechanical systems, with an emphasis on computational methods. Topics include nonlinear dynamics of passive robots (walkers, swimmers, flyers), motion planning, robust and optimal control, reinforcement learning/approximate optimal control, and the influence of mechanical design on control. Includes examples from biology and applications to legged locomotion, compliant manipulation, underwater robots, and flying machines.
R. Tedrake

6.833 The Human Intelligence Enterprise
______

Graduate (Spring)
(Subject meets with6.803)
Prereq: 6.034
Units: 3-0-9
______
Analyzes seminal work directed at the development of a computational understanding of human intelligence, such as work on learning, language, vision, event representation, commonsense reasoning, self reflection, story understanding, and analogy. Reviews visionary ideas of Turing, Minsky, and other influential thinkers. Examines the implications of work on brain scanning, developmental psychology, and cognitive psychology. Emphasis on discussion and analysis of original papers. Requires the completion of additional exercises and a substantial term project. Enrollment limited.
P. H. Winston

6.834[J] Cognitive Robotics
______

Graduate (Spring)
(Same subject as16.412[J])
Prereq: 6.041B, 6.042, or 16.09; 16.413 or 6.034
Units: 3-0-9
______
Algorithms and paradigms for creating a wide range of robotic systems that act intelligently and robustly, by reasoning extensively from models of themselves and their world. Examples range from autonomous Mars explorers and cooperative air vehicles, to everyday embedded devices. Topics include deduction and search in real-time; temporal, decision-theoretic and contingency planning; dynamic execution and re-planning; reasoning about hidden state and failures; reasoning under uncertainty, path planning, mapping and localization, and cooperative and distributed robotics.
B. C. Williams

6.835 Intelligent Multimodal User Interfaces
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 6.005, 6.031, 6.034, or permission of instructor
Units: 3-0-9
______
Implementation and evaluation of intelligent multi-modal user interfaces, taught from a combination of hands-on exercises and papers from the original literature. Topics include basic technologies for handling speech, vision, pen-based interaction, and other modalities, as well as various techniques for combining modalities. Substantial readings and a term project, where students build an interface to illustrate one or more themes of the course.
R. Davis

6.836 Multicore Programming
______

Graduate (Spring)
(Subject meets with6.816)
Prereq: 6.006
Units: 4-0-8
URL: http://web.mit.edu/6.836
______
Introduces principles and core techniques for programming multicore machines. Topics include locking, scalability, concurrent data structures, multiprocessor scheduling, load balancing, and state-of-the-art synchronization techniques, such as transactional memory. Includes sequence of programming assignments on a large multicore machine, culminating with the design of a highly concurrent application. Students taking graduate version complete additional assignments.
N. Shavit

6.837 Computer Graphics
______

Undergrad (Fall)
Prereq: Calculus II (GIR), 6.005 or 6.031; or permission of instructor
Units: 3-0-9
Lecture: TR2.30-4 (4-370)
______
Introduction to computer graphics algorithms, software and hardware. Topics include ray tracing, the graphics pipeline, transformations, texture mapping, shadows, sampling, global illumination, splines, animation and color.
F. P. Durand, W. Matusik
No textbook information available

6.838 Advanced Topics in Computer Graphics
______

Graduate (Spring) Can be repeated for credit
Prereq: 6.837
Units: 3-0-9
URL: https://ocw-int.mit.edu/6/6.838/f02/index.html
______
In-depth study of an active research topic in computer graphics. Topics change each term. Readings from the literature, student presentations, short assignments, and a programming project.
W. Matusik

6.839 Advanced Computer Graphics
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.06, 6.005, 6.031, 6.837, or permission of instructor
Units: 3-0-9
______
A graduate level course investigates computational problems in rendering, animation, and geometric modeling. The course draws on advanced techniques from computational geometry, applied mathematics, statistics, scientific computing and other. Substantial programming experience required.
W. Matusik

6.840[J] Theory of Computation
______

Graduate (Fall)
(Same subject as18.4041[J])
(Subject meets with18.404)
Prereq: 18.200 or 18.062J
Units: 4-0-8
URL: http://math.mit.edu/classes/18.404
1st mtg Sept 8 at 2.30. Room 54-100. Lecture: TR2.30-4 (2-190) Recitation: F12 (2-143) or F1 (2-139) or F2 (2-139) +final
______
A more extensive and theoretical treatment of the material in 6.045J/18.400J, emphasizing computability and computational complexity theory. Regular and context-free languages. Decidable and undecidable problems, reducibility, recursive function theory. Time and space measures on computation, completeness, hierarchy theorems, inherently complex problems, oracles, probabilistic computation, and interactive proof systems. Students in Course 18 must register for the undergraduate version, 18.404.
M. Sipser
Textbooks (Fall 2016)

6.841[J] Advanced Complexity Theory
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as18.405[J])
Prereq: 18.404
Units: 3-0-9
______
Current research topics in computational complexity theory. Nondeterministic, alternating, probabilistic, and parallel computation models. Boolean circuits. Complexity classes and complete sets. The polynomial-time hierarchy. Interactive proof systems. Relativization. Definitions of randomness. Pseudo-randomness and derandomizations. Interactive proof systems and probabilistically checkable proofs.
D. Moshkovitz

6.842 Randomness and Computation
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.046, 6.840
Units: 3-0-9
______
The power and sources of randomness in computation. Connections and applications to computational complexity, computational learning theory, cryptography and combinatorics. Topics include: probabilistic proofs, uniform generation and approximate counting, Fourier analysis of Boolean functions, computational learning theory, expander graphs, pseudorandom generators, derandomization.
R. Rubinfeld

6.845 Quantum Complexity Theory
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.045, 6.840, 18.435
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduction to quantum computational complexity theory, the study of the fundamental capabilities and limitations of quantum computers. Topics include complexity classes, lower bounds, communication complexity, proofs and advice, and interactive proof systems in the quantum world; classical simulation of quantum circuits. The objective is to bring students to the research frontier.
S. Aaronson

6.846 Parallel Computing
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: 6.004 or permission of instructor
Units: 3-0-9
______
Introduction to parallel and multicore computer architecture and programming. Topics include the design and implementation of multicore processors; networking, video, continuum, particle and graph applications for multicores; communication and synchronization algorithms and mechanisms; locality in parallel computations; computational models, including shared memory, streams, message passing, and data parallel; multicore mechanisms for synchronization, cache coherence, and multithreading. Performance evaluation of multicores; compilation and runtime systems for parallel computing. Substantial project required.
A. Agarwal

6.849 Geometric Folding Algorithms: Linkages, Origami, Polyhedra
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 6.046 or permission of instructor
Units: 3-0-9
URL: http://courses.csail.mit.edu/6.849/
______
Covers discrete geometry and algorithms underlying the reconfiguration of foldable structures, with applications to robotics, manufacturing, and biology. Linkages made from one-dimensional rods connected by hinges: constructing polynomial curves, characterizing rigidity, characterizing unfoldable versus locked, protein folding. Folding two-dimensional paper (origami): characterizing flat foldability, algorithmic origami design, one-cut magic trick. Unfolding and folding three-dimensional polyhedra: edge unfolding, vertex unfolding, gluings, Alexandrov's Theorem, hinged dissections.
E. D. Demaine

6.850 Geometric Computing
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 6.046
Units: 3-0-9
______
Introduction to the design and analysis of algorithms for geometric problems, in low- and high-dimensional spaces. Algorithms: convex hulls, polygon triangulation, Delaunay triangulation, motion planning, pattern matching. Geometric data structures: point location, Voronoi diagrams, Binary Space Partitions. Geometric problems in higher dimensions: linear programming, closest pair problems. High-dimensional nearest neighbor search and low-distortion embeddings between metric spaces. Geometric algorithms for massive data sets: external memory and streaming algorithms. Geometric optimization.
P. Indyk

6.851 Advanced Data Structures
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.046
Units: 3-0-9
URL: http://courses.csail.mit.edu/6.851/
______
More advanced and powerful data structures for answering several queries on the same data. Such structures are crucial in particular for designing efficient algorithms. Dictionaries; hashing; search trees. Self-adjusting data structures; linear search; splay trees; dynamic optimality. Integer data structures; word RAM. Predecessor problem; van Emde Boas priority queues; y-fast trees; fusion trees. Lower bounds; cell-probe model; round elimination. Dynamic graphs; link-cut trees; dynamic connectivity. Strings; text indexing; suffix arrays; suffix trees. Static data structures; compact arrays; rank and select. Succinct data structures; tree encodings; implicit data structures. External-memory and cache-oblivious data structures; B-trees; buffer trees; tree layout; ordered-file maintenance. Temporal data structures; persistence; retroactivity.
E. D. Demaine

6.852[J] Distributed Algorithms
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as18.437[J])
Prereq: 6.046
Units: 3-0-9
URL: http://theory.csail.mit.edu/classes/6.852/
Subject Cancelled Subject Cancelled
______
Design and analysis of concurrent algorithms, emphasizing those suitable for use in distributed networks. Process synchronization, allocation of computational resources, distributed consensus, distributed graph algorithms, election of a leader in a network, distributed termination, deadlock detection, concurrency control, communication, and clock synchronization. Special consideration given to issues of efficiency and fault tolerance. Formal models and proof methods for distributed computation.
N. A. Lynch

6.853 Topics in Algorithmic Game Theory
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 6.006 or 6.046
Units: 3-0-9
URL: http://people.csail.mit.edu/costis/6896sp10/
______
Presents research topics at the interface of computer science and game theory, with an emphasis on algorithms and computational complexity. Explores the types of game-theoretic tools that are applicable to computer systems, the loss in system performance due to the conflicts of interest of users and administrators, and the design of systems whose performance is robust with respect to conflicts of interest inside the system. Algorithmic focus is on algorithms for equilibria, the complexity of equilibria and fixed points, algorithmic tools in mechanism design, learning in games, and the price of anarchy.
K. Daskalakis

6.854[J] Advanced Algorithms
______

Graduate (Fall)
(Same subject as18.415[J])
Prereq: 6.041B, 6.042, or 18.600; 6.046
Units: 5-0-7
URL: http://theory.lcs.mit.edu/classes/6.854/
Lecture: MWF2.30-4 (32-141)
______
First-year graduate subject in algorithms. Emphasizes fundamental algorithms and advanced methods of algorithmic design, analysis, and implementation. Surveys a variety of computational models and the algorithms for them. Data structures, network flows, linear programming, computational geometry, approximation algorithms, online algorithms, parallel algorithms, external memory, streaming algorithms.
A. Moitra, D. R. Karger
No required or recommended textbooks

6.856[J] Randomized Algorithms
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as18.416[J])
Prereq: 6.854J, 6.041B or 6.042J
Units: 5-0-7
______
Studies how randomization can be used to make algorithms simpler and more efficient via random sampling, random selection of witnesses, symmetry breaking, and Markov chains. Models of randomized computation. Data structures: hash tables, and skip lists. Graph algorithms: minimum spanning trees, shortest paths, and minimum cuts. Geometric algorithms: convex hulls, linear programming in fixed or arbitrary dimension. Approximate counting; parallel algorithms; online algorithms; derandomization techniques; and tools for probabilistic analysis of algorithms.
D. R. Karger

6.857 Network and Computer Security
______

Graduate (Spring)
Prereq: 6.033, 6.042J
Units: 4-0-8
URL: http://web.mit.edu/6.857/www/
______
Emphasis on applied cryptography and may include: basic notion of systems security, crypotographic hash functions, symmetric crypotography (one-time pad, stream ciphers, block ciphers), cryptanalysis, secret-sharing, authentication codes, public-key cryptography (encryption, digital signatures), public-key attacks, web browser security, biometrics, electronic cash, viruses, electronic voting, Assignments include a group final project. Topics may vary year to year.
R. L. Rivest

6.858 Computer Systems Security
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.033, 6.005 or 6.031
Units: 3-6-3
URL: http://css.csail.mit.edu/6.858/
Subject Cancelled Subject Cancelled
______
Design and implementation of secure computer systems. Lectures cover attacks that compromise security as well as techniques for achieving security, based on recent research papers. Topics include operating system security, privilege separation, capabilities, language-based security, cryptographic network protocols, trusted hardware, and security in web applications and mobile phones. Labs involve implementing and compromising a web application that sandboxes arbitrary code, and a group final project.
N. B. Zeldovich

6.859[J] Integer Programming and Combinatorial Optimization
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as15.083[J])
Prereq: 15.081J or permission of instructor
Units: 4-0-8
______
In-depth treatment of the modern theory of integer programming and combinatorial optimization, emphasizing geometry, duality, and algorithms. Topics include formulating problems in integer variables, enhancement of formulations, ideal formulations, integer programming duality, linear and semidefinite relaxations, lattices and their applications, the geometry of integer programming, primal methods, cutting plane methods, connections with algebraic geometry, computational complexity, approximation algorithms, heuristic and enumerative algorithms, mixed integer programming and solutions of large-scale problems.
D. J. Bertsimas, A. S. Schulz

6.860[J] Statistical Learning Theory and Applications
(New)
______

Graduate (Fall)
(Same subject as9.520[J])
Prereq: 6.867, 6.041B, 18.06, or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (46-3310)
______
Provides students with the knowledge needed to use and develop advanced machine learning solutions to challenging problems. Covers foundations and recent advances of machine learning in the framework of statistical learning theory. Focuses on regularization techniques key to high-dimensional supervised learning. Starting from classical methods such as regularization networks and support vector machines, addresses state-of-the-art techniques based on principles such as geometry or sparsity, and discusses a variety of algorithms for supervised learning, feature selection, structured prediction, and multitask learning. Also focuses on unsupervised learning of data representations, with an emphasis on hierarchical (deep) architectures.
T. Poggio, L. Rosasco
No required or recommended textbooks

6.861[J] Aspects of a Computational Theory of Intelligence
(New)
______

Graduate (Fall)
(Same subject as9.523[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: F11-2 (46-3189)
______
Integrates neuroscience, cognitive and computer science to explore the nature of intelligence, how it is produced by the brain, and how it can be replicated in machines. Discusses an array of current research connected through an overarching theme of how it contributes to a computational account of how humans analyze dynamic visual imagery to understand objects and actions in the world.
T. Poggio, S. Ullman
No required or recommended textbooks

6.862 Applied Machine Learning
(New)
______

Graduate (Spring)
(Subject meets with6.036)
Prereq: Permission of instructor
Units: 4-0-8
______
Introduces principles, algorithms, and applications of machine learning from the point of view of modeling and prediction; formulation of learning problems; representation, over-fitting, generalization; clustering, classification, probabilistic modeling; and methods such as support vector machines, hidden Markov models, and Bayesian networks. Students taking graduate version complete different assignments.
R. Barzilay, T. Jaakkola

6.863[J] Natural Language and the Computer Representation of Knowledge
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as9.611[J])
Prereq: 6.034
Units: 3-3-6
______
Explores the relationship between computer representation of knowledge and the structure of natural language. Emphasizes development of analytical skills necessary to judge the computational implications of grammatical formalisms, and uses concrete examples to illustrate particular computational issues. Efficient parsing algorithms for context-free grammars; Treebank grammars and statistical parsing. Question answering systems. Extensive laboratory work on building natural language processing systems. 8 Engineering Design Points.
R. C. Berwick

6.864 Advanced Natural Language Processing
______

Graduate (Fall)
(Subject meets with6.806)
Prereq: 6.046 or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (32-123)
______
Introduces the study of human language from a computational perspective, including syntactic, semantic and discourse processing models. Emphasizes machine learning methods and algorithms. Uses these methods and models in applications such as syntactic parsing, information extraction, statistical machine translation, dialogue systems, and summarization. Students taking graduate version complete additional assignments.
R. A. Barzilay
No textbook information available

6.865 Advanced Computational Photography
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with6.815)
Prereq: Calculus II (GIR), 6.005 or 6.031
Units: 3-0-9
______
Presents fundamentals and applications of hardware and software techniques used in digital and computational photography, with an emphasis on software methods. Provides sufficient background to implement solutions to photographic challenges and opportunities. Topics include cameras and image formation, image processing and image representations, high-dynamic-range imaging, human visual perception and color, single view 3-D model reconstruction, morphing, data-rich photography, super-resolution, and image-based rendering. Students taking graduate version complete additional assignments.
F. P. Durand

6.866 Machine Vision
______

Not offered academic year 2017-2018Graduate (Fall)
(Subject meets with6.801)
Prereq: 6.003 or permission of instructor
Units: 3-0-9
Lecture: TR9.30-11 (32-124)
______
Intensive introduction to the process of generating a symbolic description of the environment from an image. Students expected to attend the 6.801 lectures as well as occasional seminar meetings on special topics. Material presented in 6.801 is supplemented by reading from the literature. Students required to implement a project on a topic of their choice from the material covered.
B. K. P. Horn
Textbooks (Fall 2016)

6.867 Machine Learning
______

Graduate (Fall)
Prereq: 6.041B or 18.600, 18.06
Units: 3-0-9
Lecture: TR9.30-11 (26-100) Recitation: F9 (26-322) or F10 (26-322) or F11 (26-322) or F12 (26-322) or F1 (26-322) or F2 (26-322) or F3 (26-322) or F4 (26-322) or F9 (36-144) or F10 (36-144) or F11 (36-144) or F12 (56-154) or F1 (56-154) or F2 (56-154) or F3 (56-154) or F4 (56-154)
______
Principles, techniques, and algorithms in machine learning from the point of view of statistical inference; representation, generalization, and model selection; and methods such as linear/additive models, active learning, boosting, support vector machines, non-parametric Bayesian methods, hidden Markov models, and Bayesian networks. Recommended prerequisite: 6.036.
T. Jaakkola, L. P. Kaelbling
Textbooks (Fall 2016)

6.868[J] The Society of Mind
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject asMAS.731[J])
Prereq: Must have read "The Society of Mind" and "The Emotion Machine"; permission of instructor
Units: 2-0-10
URL: http://web.media.mit.edu/~dustin/6.868/
______
Introduction to a theory that tries to explain how minds are made from collections of simpler processes. Treats such aspects of thinking as vision, language, learning, reasoning, memory, consciousness, ideals, emotions, and personality. Incorporates ideas from psychology, artificial intelligence, and computer science to resolve theoretical issues such as wholes vs. parts, structural vs. functional descriptions, declarative vs. procedural representations, symbolic vs. connectionist models, and logical vs. common-sense theories of learning. Enrollment limited.
M. Minsky

6.869 Advances in Computer Vision
______

Graduate (Fall)
(Subject meets with6.819)
Prereq: 6.041B or 6.042; 18.06
Units: 3-0-9
Lecture: TR9.30-11 (34-101)
______
Advanced topics in computer vision with a focus on the use of machine learning techniques and applications in graphics and human-computer interface. Covers image representations, texture models, structure-from-motion algorithms, Bayesian techniques, object and scene recognition, tracking, shape modeling, and image databases. Applications may include face recognition, multimodal interaction, interactive systems, cinematic special effects, and photorealistic rendering. Covers topics complementary to 6.866. Students taking graduate version complete additional assignments.
W. T. Freeman, A. Torralba
No textbook information available

6.870 Advanced Topics in Computer Vision
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: 6.801, 6.869, or permission of instructor
Units: 3-0-9
______
Seminar exploring advanced research topics in the field of computer vision; focus varies with lecturer. Typically structured around discussion of assigned research papers and presentations by students. Example research areas explored in this seminar include learning in vision, computational imaging techniques, multimodal human-computer interaction, biomedical imaging, representation and estimation methods used in modern computer vision.
W. T. Freeman, B. K. P. Horn, A. Torralba

6.871 Performance Engineering of Software Systems
______

Graduate (Fall)
(Subject meets with6.172)
Prereq: 6.004, 6.006, 6.005 or 6.031
Units: 3-12-3
URL: http://www.ai.mit.edu/courses/6.871/
Lecture: TR2.30-4 (34-101) Lab: F10-12 (4-265) or F1-3 (4-265) or F3-5 (4-265) or F10-12 (24-307) or F1-3 (34-301) or F3-5 (34-301) or F2-4 (34-304) or F3-5 (36-155)
______
Project-based introduction to building efficient, high-performance and scalable software systems. Topics include performance analysis, algorithmic techniques for high performance, instruction-level optimizations, vectorization, cache and memory hierarchy optimization, and parallel programming. Students taking graduate version complete additional assignments.
S. Amarasinghe, C. E. Leiserson
No textbook information available

6.872[J] Biomedical Computing
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject asHST.950[J])
Prereq: 6.034, 6.036, or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Analyzes computational needs of clinical medicine, reviews systems and approaches that have been used to support those needs, and the relationship between clinical data and gene and protein measurements to support precision medicine. Topics include the nature of clinical data, architecture and design of healthcare information systems, privacy and security issues, medical expert systems, predictive models and machine learning from big data in healthcare, and an introduction to bioinformatics. Case studies and guest lectures describe contemporary institutions, systems, and research projects. Term project using large clinical and genomic data sets integrates classroom topics.
G. Alterovitz, P. Szolovits

6.874[J] Computational Systems Biology
______

Graduate (Spring)
(Same subject asHST.506[J])
(Subject meets with6.802[J],20.390[J],20.490)
Prereq: Biology (GIR); 18.600 or 6.041B
Units: 3-0-9
______
Presents advanced machine learning and algorithmic approaches for contemporary problems in biology drawing upon recent advances in the literature. Topics include biological discovery in heterogeneous cellular populations; single cell data analysis; regulatory factor binding; motif discovery; gene expression analysis; regulatory networks (discovery, validation, data integration, protein-protein interactions, signaling, chromatin accessibility analysis); predicting phenotype from genotype; and experimental design (model validation, interpretation of interventions). Computational methods presented include deep learning, dimensionality reduction, clustering, directed and undirected graphical models, significance testing, Dirichlet processes, and topic models. Multidisciplinary team-oriented final research project.
D. K. Gifford

6.875[J] Cryptography and Cryptanalysis
______

Graduate (Spring)
(Same subject as18.425[J])
Prereq: 6.046J
Units: 3-0-9
______
A rigorous introduction to modern cryptography. Emphasis on the fundamental cryptographic primitives of public-key encryption, digital signatures, pseudo-random number generation, and basic protocols and their computational complexity requirements.
S. Goldwasser, S. Micali

6.876 Advanced Topics in Cryptography
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: 6.875
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Recent results in cryptography, interactive proofs, and cryptographic game theory.
S. Goldwasser, S. Micali

6.878[J] Advanced Computational Biology: Genomes, Networks, Evolution
______

Graduate (Fall)
(Same subject asHST.507[J])
(Subject meets with6.047)
Prereq: 6.006, 6.041B, Biology (GIR); or permission of instructor
Units: 4-0-8
Lecture: TR1-2.30 (32-141) Recitation: F3 (4-237)
______
See description for 6.047. Additionally examines recent publications in the areas covered, with research-style assignments. A more substantial final project is expected, which can lead to a thesis and publication.
M. Kellis
No textbook information available

6.881, 6.882 Advanced Topics in Artificial Intelligence
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______

6.883 Advanced Topics in Artificial Intelligence
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______

6.884 Advanced Topics in Artificial Intelligence
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Advanced study of topics in artificial intelligence. Specific focus varies from year to year. Consult department for details.
Consult Department

6.885-6.888 Advanced Topics in Computer Systems
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Advanced study of topics in computer systems. Specific focus varies from year to year. Consult department for details.
Consult Department

6.889-6.893 Advanced Topics in Theoretical Computer Science
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
6.889: URL: http://www.eecs.mit.edu/academics-admissions/academic-information/subject-updates-ft-2016
6.889: Lecture: TR1-2.30 (1-190)
______
Advanced study of topics in theoretical computer science. Specific focus varies from year to year. Consult department for details.
Consult Department
6.889: No textbook information available

6.894-6.896 Advanced Topics in Graphics and Human-Computer Interfaces
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Advanced study of topics in graphics and human-computer interfaces. Specific focus varies from year to year. Consult department for details.
Consult Department

6.901[J] Innovation Engineering: Moving Ideas to Impact
(New)
______

Undergrad (Fall)
(Same subject as15.359[J])
Prereq: None
Units: 3-3-6
URL: http://www.mit.edu:8001/courses/6.901/patent.html
Lecture: TR9-10.30 (1-390)
______
Designed for students to gain the perspective of a Chief Technology Officer of a start-up, large corporation, or a not-for-profit. Details the innovation process, from an idea's inception through impact in the economy, regardless of organizational setting. Explores how solutions are developed to become ready for broader market deployment. Includes testing and development of the problem-solution fit, probing of solutions for robustness, and testing of both technical and operational scaling of proposed solutions. Examines the human aspects of innovation, specifically issues of team building and readiness. Considers the broader system for innovation, including the role of key stakeholders in shaping its success in order to arrive at an impactful solution. Addresses intellectual property, the effect of regulations and social and cultural differences across varied global markets, and the personal skillset necessary to align and manage these issues.
V. Bulovic, F. Murray
No textbook information available

6.902 Engineering Innovation and Design
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:2.723,6.902,16.662)
Prereq: None
Units: 3-0-3
Lecture: M EVE (7-9 PM) (32-155) Recitation: M EVE (9 PM) (32-155) or W EVE (7 PM) (2-105) or W EVE (8 PM) (2-105)
______
Project-based seminar in innovative design thinking develops students' ability to conceive, implement, and evaluate successful projects in any engineering discipline. Lectures focus on the iterative design process and techniques to enhance creative analysis. Students use this process to design and implement robust voice recognition applications using a simple web-based system. They also give presentations and receive feedback to sharpen their communication skills for high emotional and intellectual impact. Guest lectures illustrate multidisciplinary approaches to design thinking.
B. Kotelly
No textbook information available

6.903 Patents, Copyrights, and the Law of Intellectual Property
______

Undergrad (Spring)
Prereq: None
Units: 3-0-6
______
Intensive introduction to the US law of intellectual property with major emphasis on patents, including the process of patent application and the remedies for patent infringement. Also focuses on copyrights and provides a brief look at trademarks and trade secrets. Presents comparisons of what can and cannot be protected, and what rights the owner does and does not obtain. Highlights issues relating to information technology, biogenetic materials, and business methods. Readings include judicial opinions and statutory material. No listeners.
S. M. Bauer

6.904 Ethics for Engineers
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.082,2.900,6.904,10.01,22.014)
Prereq: None
Units: 2-0-4
Lecture: M3-5 (66-144, 36-153) or T3-5 (37-212) or T EVE (7.30-9.30 PM) (66-144) or W3-5 (36-153)
______
Integrates classical readings that provide an overview of ethics with a survey of case studies that focus on ethical problems arising in the practice of engineering. Readings taken from a variety of sources, such as Aristotle, Machiavelli, Bacon, Hobbes, Locke, the Founding Fathers, and the Bible. Case studies include written analyses and films that address engineering disasters, biotechnology, court cases, ethical codes, and the ultimate scope and aims of engineering.
D. Doneson, B. L. Trout
No textbook information available

6.905 Large-scale Symbolic Systems
______

Undergrad (Spring)
(Subject meets with6.945)
Prereq: 6.034 or permission of instructor
Units: 3-0-9
______
Concepts and techniques for the design and implementation of large software systems that can be adapted to uses not anticipated by the designer. Applications include compilers, computer-algebra systems, deductive systems, and some artificial intelligence applications. Covers means for decoupling goals from strategy, mechanisms for implementing additive data-directed invocation, work with partially-specified entities, and how to manage multiple viewpoints. Topics include combinators, generic operations, pattern matching, pattern-directed invocation, rule systems, backtracking, dependencies, indeterminacy, memoization, constraint propagation, and incremental refinement. Students taking graduate version complete additional assignments.
G. J. Sussman

6.906 StartMIT: Workshop for Entrepreneurs and Innovators
______

Undergrad (IAP)
(Subject meets with6.936)
Prereq: None
Units: 4-0-2 [P/D/F]
______
Designed for students who are interested in entrepreneurship and want to explore the potential commercialization of their research project. Introduces practices for building a successful company, such as idea creation and validation, defining a value proposition, building a team, marketing, customer traction, and possible funding models. Students taking graduate version complete different assignments.
A. Chandrakasan

6.910 Independent Study in Electrical Engineering and Computer Science
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Consult department TBA.
______
Opportunity for independent study at the undergraduate level under regular supervision by a faculty member. Projects require prior approval.
Consult Department Undergraduate Office
No textbook information available

6.911 Engineering Leadership Lab
(ESD.05)
______

Undergrad (Fall, Spring) Can be repeated for credit
Engineering School-Wide Elective Subject.
(Offered under:6.911,16.650)
(Subject meets with6.913[J],16.667[J])
Prereq: None.Coreq: 6.912 or permission of instructor
Units: 0-2-1
Lab: F9-11 (32-124) or F1-3 (32-124) or F3-5 (32-124)
______
Exposes students to engineering frameworks, models, and cases in an interactive, experience-based environment, and hones leadership skills. Students participate in guided reflection on successes and discover opportunities for improvement in a controlled setting. Activities include design-implement activities, role-playing, simulations, case study analysis, and performance assessment by and of other students. Content throughout the term is frequently student-driven. First-year GEL Program students register for 6.911. Second-year GEL Program students register for 6.913. Preference to first-year students in the Bernard M. Gordon-MIT Engineering Leadership Program.
L. McGonagle, J. Feiler
No required or recommended textbooks

6.912 Engineering Leadership
(ESD.054)
______

Undergrad (Fall, Spring) Can be repeated for credit
Engineering School-Wide Elective Subject.
(Offered under:6.912,16.651)
Prereq: None.Coreq: 6.911 or permission of instructor
Units: 1-0-2
Lecture: M9-10.30 (5-233) or M11-12.30 (5-233) or T9-10.30 (5-233) or T11-12.30 (5-233)
______
Exposes students to the models and methods of engineering leadership within the contexts of conceiving, designing, implementing and operating products, processes and systems. Introduces models and theories, such as the Four Capabilities Framework and the Capabilities of Effective Engineering Leaders. Discusses the appropriate times and reasons to use particular models to deliver engineering success. Includes guest speakers and team projects that change from term to term. May be repeated for credit once with permission of instructor. Preference to first-year students in the Gordon Engineering Leadership Program.
J. Magarian, J. Schindall, L. McGonagle
No required or recommended textbooks

6.913 Engineering Leadership Lab
(ESD.050)
______

Undergrad (Fall, Spring) Can be repeated for credit
Engineering School-Wide Elective Subject.
(Offered under:6.913,16.667)
(Subject meets with6.911[J],16.650[J])
Prereq: 6.911
Units: 0-2-4
Lab: F9-11 (32-124) or F1-3 (32-124) or F3-5 (32-124)
______
Exposes students to engineering frameworks, models, and cases in an interactive, experience-based environment, and hones leadership skills. Students participate in guided reflection on successes and discover opportunities for improvement in a controlled setting. Activities include design-implement activities, role-playing, simulations, case study analysis, and performance assessment by and of other students. Content throughout the term is frequently student-driven. First year GEL Program students register for 6.911. Second year GEL Program students register for 6.913. Preference to second-year students in the Bernard M. Gordon-MIT Engineering Leadership Program.
L. McGonagle, J. Feiler
No required or recommended textbooks

6.914 Project Engineering
(ESD.052)
______

Undergrad (IAP)
Engineering School-Wide Elective Subject.
(Offered under:6.914,16.669)
Prereq: 6.911 or permission of instructor
Units: 1-2-1 [P/D/F]
Credit cannot also be received for1.040
______
Students attend a four-day off-site workshop where an introduction to basic principles, methods, and tools for project management in a realistic context are covered. In teams, students create a plan for a project of their choice; past projects include Debris Removal in Haiti and Food Preparation Robot for Restaurants. Develops skills applicable to the management of complex development projects. Topics include cost-benefit analysis, resource and cost estimation, and project control and delivery. Case studies highlight projects in both hardware/construction and software. Preference to students in the Bernard M. Gordon-MIT Engineering Leadership Program.
O. de Weck

6.915[J] Leading Creative and Innovative Teams
(New)
______

Undergrad (Spring)
(Same subject as16.671[J])
Prereq: None
Units: 6-0-6
______
Empowers future leaders in technology by developing a foundation of personal and team leadership skills. Grounded in research and theory, focuses on practical leadership skills and how they can be assessed, learned, and applied to group situations in technical and engineering contexts. Focuses on how to foster original and creative thinking in groups, and how groups can successfully move creative ideas toward implementation and value creation. Balances traditional learning methods and more experiential ones, such as role play simulations and project-based learning. Enrollment limited to seating capacity of classroom. Admittance may be controlled by lottery.
D. Nino, J. Schindall

6.920 Practical Work Experience
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units: 0-1-0 [P/D/F]
URL: http://www.eecs.mit.edu/ug/programs.html#6.910
Consult department TBA.
______
For Course 6 students participating in curriculum-related off-campus work experiences in electrical engineering or computer science. Before enrolling, students must have an employment offer from a company or organization and must find an EECS supervisor. Upon completion of the work the student must submit a letter from the employer evaluating the work accomplished, a substantive final report from the student, approved by the MIT supervisor. Subject to departmental approval. Consult Department Undergraduate Office for details on procedures and restrictions.
Consult Department Undergraduate Office
No textbook information available

6.921 6-A Internship
______

Undergrad (Summer)
Prereq: None
Units: 0-12-0 [P/D/F]
______
Provides academic credit for the first assignment of 6-A undergraduate students at companies affiliated with the department's 6-A internship program. Limited to students participating in the 6-A internship program.
T. Palacios
No textbook information available

6.922 Advanced 6-A Internship
______

Undergrad (Spring, Summer)
Prereq: 6.921
Units: 0-12-0 [P/D/F]
______
Provides academic credit for the second assignment of 6-A undergraduate students at companies affiliated with the department's 6-A internship program. Limited to students participating in the 6-A internship program.
T. Palacios
No textbook information available

6.928[J] Leading Creative Teams
(New)
______

Graduate (Fall, Spring)
(Same subject as16.990[J])
Prereq: None
Units: 3-1-5
Lecture: F9.30-12.30 (5-233) Lab: W3 (56-154) or F12.30 (5-233)
______
Prepares students to lead teams charged with developing creative solutions to challenging problems. Grounded in research but practical in focus, covers the development of basic leadership capabilities, such as motivating and influencing others, delegating, managing conflict, and communicating effectively; how to create, launch, develop, and adjourn teams; and how to foster creativity in small groups.
D. Nino, J. Schindall
No textbook information available

6.929[J] Energy Technology and Policy: From Principles to Practice
______

Graduate (Spring)
(Same subject as5.00[J],10.579[J],22.813[J])
Prereq: None
Units: 3-0-6
______
Develops analytical skills to lead a successful technology implementation with an integrated approach that combines technical, economical and social perspectives. Considers corporate and government viewpoints as well as international aspects, such as nuclear weapons proliferation and global climate issues. Discusses technologies such as oil and gas, nuclear, solar, and energy efficiency. Limited to 100.
J. Deutch

6.930 Management in Engineering
______

Undergrad (Fall)
Engineering School-Wide Elective Subject.
(Offered under:2.96,6.930,10.806,16.653)
Prereq: None
Units: 3-1-8
Lecture: MW11-12.30 (35-225) Lab: M4 (35-308) or T10 (1-273) or R4 (1-371) or F1 (1-132) or F2 (1-132)
______
Introduction and overview of engineering management. Financial principles, management of innovation, technical strategy and best management practices. Case study method of instruction emphasizes participation in class discussion. Focus is on the development of individual skills and management tools. Restricted to juniors and seniors.
H. S. Marcus, J.-H. Chun
No textbook information available

6.932[J] Linked Data Ventures
______

Graduate (Spring)
(Same subject as15.377[J])
Prereq: 6.005, 6.033, or permission of instructor
Units: 3-0-9
______
Provides practical experience in the use and development of semantic web technologies. Focuses on gaining practical insight from executives and practitioners who use these technologies in their companies. Working in multidisciplinary teams, students complete a term project to develop a sustainable prototype. Concludes with a professional presentation, judged by a panel of experts, and a technical presentation to faculty.
T. Berners-Lee, L. Kagal, K. Rae, R. Sturdevant

6.933 Entrepreneurship in Engineering: The Founder's Journey
______

Graduate (Fall)
Prereq: None
Units: 4-0-8
Lecture: TR EVE (7-9 PM) (32-141)
______
Immerses students in the experience of an engineer who founds a start-up company. Examines leadership, innovation, and creativity through the lens of an entrepreneur. Suitable for students interested in transforming an idea into a business or other realization for wide-scale societal impact. Covers critical aspects of validating ideas and assessing personal attributes needed to activate and lead a growing organization. Teams explore the basics of new venture creation and experimentation. Emphasizes personal skills and practical experiences. No listeners.
C. Chase
No textbook information available

6.935[J] Financial Market Dynamics and Human Behavior
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as15.481[J])
Prereq: 15.401, 15.414, or 15.415
Units: 4-0-5
______
Develops a new perspective on the dynamics of financial markets and the roles that human behavior and the business environment play in determining the evolution of behavior and institutions. Draws on a variety of disciplines to develop a more complete understanding of human behavior in the specific context of markets and other economic institutions. Incorporates practical applications from financial markets, the hedge fund industry, private equity, government regulation, and political economy. Students use ideas from this new perspective to formulate several new hypotheses regarding recent challenges to traditional economic thinking.
A. Lo

6.936 StartMIT: Workshop for Entrepreneurs and Innovators
______

Graduate (IAP)
(Subject meets with6.906)
Prereq: None
Units: 4-0-2 [P/D/F]
______
Designed for students who are interested in entrepreneurship and want to explore the potential commercialization of their research project. Introduces practices for building a successful company, such as idea creation and validation, defining a value proposition, building a team, marketing, customer traction, and possible funding models. Students taking graduate version complete different assignments.
A. Chandrakasan

6.941 Statistics for Research Projects: Statistical Modeling and Experiment Design
______

Graduate (IAP)
Not offered regularly; consult department
Prereq: None
Units: 2-2-2 [P/D/F]
______
Practical introduction to data analysis, statistical modeling, and experimental design, intended to provide essential skills for conducting research. Covers basic techniques such as hypothesis-testing and regression models for both traditional experiments and newer paradignms such as evaluating simulations. Assignments reinforce techniques through analyzing sample datasets and reading case studies. Students with research projects will be encouraged to share their experiences and project-specific questions.
Staff

6.945 Large-scale Symbolic Systems
______

Graduate (Spring)
(Subject meets with6.905)
Prereq: 6.034 or permission of instructor
Units: 3-0-9
______
Concepts and techniques for the design and implementation of large software systems that can be adapted to uses not anticipated by the designer. Applications include compilers, computer-algebra systems, deductive systems, and some artificial intelligence applications. Covers means for decoupling goals from strategy, mechanisms for implementing additive data-directed invocation, work with partially-specified entities, and how to manage multiple viewpoints. Topics include combinators, generic operations, pattern matching, pattern-directed invocation, rule systems, backtracking, dependencies, indeterminacy, memoization, constraint propagation, and incremental refinement. Students taking graduate version complete additional assignments.
G. J. Sussman

6.946[J] Classical Mechanics: A Computational Approach
______

Graduate (Fall)
(Same subject as8.351[J],12.620[J])
Prereq: Physics I (GIR), 18.03, permission of instructor
Units: 3-3-6
Credit cannot also be received for12.008
URL: http://swissnet.ai.mit.edu/~gjs/6946/index.html
Lecture: MWF11 (54-819) Lab: W EVE (7-10 PM) (14-0637)
______
Classical mechanics in a computational framework, Lagrangian formulation, action, variational principles, and Hamilton's principle. Conserved quantities, Hamiltonian formulation, surfaces of section, chaos, and Liouville's theorem. Poincaré integral invariants, Poincaré-Birkhoff and KAM theorems. Invariant curves and cantori. Nonlinear resonances, resonance overlap and transition to chaos. Symplectic integration. Adiabatic invariants. Applications to simple physical systems and solar system dynamics. Extensive use of computation to capture methods, for simulation, and for symbolic analysis. Programming experience required. Students taking the graduate version complete additional assignments.
J. Wisdom, G. J. Sussman
Textbooks (Fall 2016)

6.951 Graduate 6-A Internship
______

Graduate (Fall, Spring, Summer)
Prereq: 6.921 or 6.922
Units: 0-12-0 [P/D/F]
TBA.
______
Provides academic credit for a graduate assignment of graduate 6-A students at companies affiliated with the department's 6-A internship program. Limited to graduate students participating in the 6-A internship program.
T. Palacios
No textbook information available

6.952 Graduate 6-A Internship
______

Graduate (Fall, Spring, Summer)
Prereq: 6.951
Units: 0-12-0 [P/D/F]
TBA.
______
Provides academic credit for graduate students who require an additional term at the company to complete the graduate assignment of the department's 6-A internship program. This academic credit is for registration purposes only and cannot be used toward fulfilling the requirements of any degree program. Limited to graduate students participating in the 6-A internship program.
T. Palacios
No textbook information available

6.960 Introductory Research in Electrical Engineering and Computer Science
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Enrollment restricted to first-year graduate students in Electrical Engineering and Computer Science who are doing introductory research leading to an SM, EE, ECS, PhD, or ScD thesis. Opportunity to become involved in graduate research, under guidance of a staff member, on a problem of mutual interest to student and supervisor. Individual programs subject to approval of professor in charge.
L. A. Kolodziejski
No textbook information available

6.961 Introduction to Research in Electrical Engineering and Computer Science
______

Graduate (Fall, Spring, Summer)
Prereq: Permission of instructor
Units: 3-0-0
Lecture: M EVE (4-6 PM) (34-301)
______
Seminar on topics related to research leading to an SM, EE, ECS, PhD, or ScD thesis. Limited to first-year regular graduate students in EECS with a fellowship or teaching assistantship.
L. A. Kolodziejski
No textbook information available

6.962 Independent Study in Electrical Engineering and Computer Science
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Opportunity for independent study under regular supervision by a faculty member. Projects require prior approval.
L. A. Kolodziejksi
No textbook information available

6.980 Teaching Electrical Engineering and Computer Science
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
Consult department TBA.
______
For qualified students interested in gaining teaching experience. Classroom, tutorial, or laboratory teaching under the supervision of a faculty member. Enrollment limited by availability of suitable teaching assignments.
H. S. Lee, R. C. Miller
No required or recommended textbooks

6.981 Teaching Electrical Engineering and Computer Science
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
Consult department TBA.
______
For Teaching Assistants in Electrical Engineering and Computer Science, in cases where teaching assignment is approved for academic credit by the department.
H. S. Lee, R. C. Miller
No required or recommended textbooks

6.991 Research in Electrical Engineering and Computer Science
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
Consult department TBA.
______
For EECS MEng students who are Research Assistants in Electrical Engineering and Computer Science, in cases where the assigned research is approved for academic credit by the department. Hours arranged with research supervisor.
Consult Department Undergraduate Office
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

6.999 Practical Experience in EECS
______

Graduate (Fall, Spring)
Prereq: None
Units arranged [P/D/F]
Consult department TBA.
______
For Course 6 students in the SM/PhD track who seek practical off-campus research experiences or internships in electrical engineering or computer science. Before enrolling, students must have a firm employment offer from a company or organization and secure a research supervisor within EECS. Employers required to document the work accomplished. Research proposals subject to departmental approval; consult departmental Graduate Office.
L. A. Kolodziejski
No required or recommended textbooks

6.EPE UPOP Engineering Practice Experience
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.EPE,2.EPE,3.EPE,6.EPE,10.EPE,16.EPE,22.EPE)
Prereq: 2.EPW or permission of instructor
Units: 0-0-1 [P/D/F]
TBA.
______
Provides sophomores with guided practice in finding opportunities and excelling in the world of practice. Building on the skills and relationships acquired in the Engineering Practice Workshop, students receive coaching to articulate goals, invoke the UPOP network of mentors and employers, identify and pursue opportunities and negotiate terms of their summer assignment. Students complete a 10-12 week internship, which includes filing three progress reports, conducting one informational interview, and possibly hosting a site visit by MIT staff. Returning to campus as juniors, UPOP students take part in reflective exercises that aid assimilation of learning objectives and reinforce the cognitive link between all aspects of the UPOP experience and disciplinary fields of study. Sequence begins in the spring of sophomore year and ends in the fall of junior year.
Staff
No textbook information available

6.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No textbook information available

6.S897-6.S899 Special Subject in Computer Science
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
6.S897: Lecture: TR11-12.30 (56-191)
6.S898: Lecture: F10-1 (5-234)
6.S899: TBA.
______
Covers subject matter not offered in the regular curriculum. Consult department to learn of offerings for a particular term.
Consult Department
6.S897: No textbook information available
6.S898: No textbook information available
6.S899: No textbook information available

6.S911-6.S919 Special Subject in Electrical Engineering and Computer Science
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Covers subject matter not offered in the regular curriculum.
Consult Department

6.S963-6.S967 Special Studies: EECS
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
Subject Cancelled 6.S963 Cancelled
6.S964: TBA.
______
Opportunity for study of graduate-level topics related to electrical engineering and computer science but not included elsewhere in the curriculum. Registration under this subject normally used for situations involving small study groups. Normal registration is for 12 units. Registration subject to approval of professor in charge. Consult the department for details.
L. A. Kolodziejski
6.S963: No textbook information available
6.S964: No textbook information available

6.S974 Special Subject in Electrical Engineering and Computer Science
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______
Covers subject matter not offered in the regular curriculum. Consult department to learn of offerings for a particular term.
Consult Department

6.S975-6.S979 Special Subject in Electrical Engineering and Computer Science
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
6.S976: Lecture: W1-4 (E14-633) +final
______
Covers subject matter not offered in the regular curriculum. Consult department to learn of offerings for a particular term.
Consult Department
6.S976: No textbook information available

6.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Consult department TBA.
______
Program of research leading to the writing of an SM, EE, ECS, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member.
L. A. Kolodziejski
Textbooks arranged individually

6.THM Master of Engineering Program Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 6.UAT
Units arranged
Consult department TBA.
______
Program of research leading to the writing of an MEng thesis; to be arranged by the student and an appropriate MIT faculty member. Restricted to MEng students who have been admitted to the MEng program.
Consult Department Undergraduate Office
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

6.UR Undergraduate Research in Electrical Engineering and Computer Science
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
Consult department TBA.
______
Individual research project arranged with appropriate faculty member or approved supervisor. Forms and instructions for the proposal and final report are available in the EECS Undergraduate Office.
Consult Department Undergraduate Office
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|6.00-6.299|6.30-6.799|6.80-6.ZZZ|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 7: Biology
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Course 7: Biology
Fall 2016


Undergraduate Subjects


Introductory Biology

All five subjects cover the same core material, comprising about 50% of the course, while the remaining material is specialized for each version as described below. Core material includes fundamental principles of biochemistry, genetics, molecular biology, and cell biology. These topics address structure and regulation of genes, structure and synthesis of proteins, how these molecules are integrated into cells and how cells communicate with one another.

7.012 Introductory Biology
______

Undergrad (Fall) Biology
Prereq: None
Units: 5-0-7
Credit cannot also be received for7.013,7.014,7.015,7.016,ES.7012,ES.7013
URL: https://biology.mit.edu/course_listings_undergraduate/701x_introductory_biology
Recs begin Sept 12. Lecture: MWF10 (26-100) Recitation: MW12 (26-204) or MW1 (26-204) or MW12 (26-210) or MW1 (26-210) or MW12 (24-307) or MW1 (24-307) or TR9 (26-204) or TR10 (26-204) or TR9 (26-210) or TR10 (26-210) or TR11 (26-204) or TR12 (26-204) or TR11 (24-112) or TR12 (24-112) or TR11 (1-135) or TR12 (1-135, 26-210) or TR1 (26-210) or TR12 (26-310) or TR1 (26-310) or TR2 (26-210) or TR3 (26-210) or TBA +final
______
Exploration into areas of current research in molecular and cell biology, immunology, neurobiology, human genetics, biochemistry, and evolution. Enrollment limited to seating capacity of classroom. Admittance may be controlled by lottery.
E. Lander, R. Weinberg
Textbooks (Fall 2016)

7.013 Introductory Biology
______

Undergrad (Spring) Biology
Prereq: None
Units: 5-0-7
Credit cannot also be received for7.012,7.014,7.015,7.016,ES.7012,ES.7013
URL: https://biology.mit.edu/course_listings_undergraduate/701x_introductory_biology
______
Genomic approaches to human biology, including neuroscience, development, immunology, tissue repair and stem cells, tissue engineering, and infectious and inherited diseases, including cancer. Enrollment limited to seating capacity of classroom. Admittance may be controlled by lottery.
A. Amon, H. Sive

7.014 Introductory Biology
______

Undergrad (Spring) Biology
Units: 5-0-7
Credit cannot also be received for7.012,7.013,7.015,7.016,ES.7012,ES.7013
URL: https://biology.mit.edu/course_listings_undergraduate/701x_introductory_biology
______
Studies the fundamental principles of biology and their application towards understanding the Earth as a dynamical system shaped by life. Focuses on molecular ecology in order to show how processes at the molecular level can illuminate macroscopic properties, including evolution and maintenance of biogeochemical cycles, and ecological interactions in ecosystems ranging from the ocean to the human gut. Includes quantitative analysis of population growth, community structure, competition, mutualism and predation; highlights their role in shaping the biosphere. Enrollment limited to seating capacity of classroom. Admittance may be controlled by lottery.
G. C. Walker, S. W. Chisholm, M. Polz

7.015 Introductory Biology
______

Undergrad (Fall) Biology
Prereq: Advanced high school course covering cellular and molecular biology, or permission of instructor
Units: 5-0-7
Credit cannot also be received for7.012,7.013,7.014,7.016,ES.7012,ES.7013
Lecture: MWF10 Recitation: TR10 (26-302) or TR12 (26-322) +final
______
Emphasizes the application of fundamental biological principles to trending topics in microbiology and immunology. Specific modules focus on antibiotic resistance, influenza, genome-wide association studies, biotechnology (such as genetically modified organisms and personal genomics), the microbiome, and diabetes. Includes discussion of the social and ethical issues surrounding modern biology. Limited to 60; admittance may be controlled by lottery.
M. Laub, H. Ploegh
Textbooks (Fall 2016)

7.016 Introductory Biology
______

Undergrad (Fall) Biology
Prereq: None
Units: 5-0-7
Credit cannot also be received for7.012,7.013,7.014,7.015,ES.7012,ES.7013
Lecture: MWF10 (34-101) Recitation: MW12 (36-156) or MW1 (36-156, 26-322) or MW2 (26-322, 26-204) or MW3 (26-204) or TR9 (26-314) or TR10 (26-314, 24-307) or TR11 (24-307, 26-314) or TR12 (26-314, 26-302) or TR1 (26-302) +final
______
Introduction to fundamental principles of biochemistry, molecular biology and genetics for understanding the functions of living systems. Covers examples of the use of chemical biology and 21st-century molecular genetics in understanding human health and therapeutic intervention. Enrollment limited to seating capacity of classroom. Admittance may be controlled by lottery.
L. Boyer, B. Imperiali
Textbooks (Fall 2016)

7.02[J] Introduction to Experimental Biology and Communication
______

Undergrad (Fall, Spring) Institute Lab
(Same subject as10.702[J])
Prereq: Biology (GIR)
Units: 4-8-6
1st mtg 9/8 mandatory. Lecture: TR11 (32-155) Lab: TR1-5 (68-074) or WF1-5 (68-074) Recitation: M9-11 (68-121) or M1-3 (66-148, 4-146) or T9-11 (4-144) or W1-3 (68-121) or W9-11 (68-121) +final
______
Introduction to the experimental concepts and methods of molecular biology, biochemistry, and genetic analysis. Emphasis on experimental design, critical data analysis, and the development of written communications skills. 12 units may be applied to the General Institute Laboratory Requirement. Concurrent registration with 7.03 strongly recommended. Enrollment limited.
Fall:T. Baker, M. Gehring, K. D. Wittrup
Spring:T. Baker, O. Yilmaz, K. D. Wittrup
No required or recommended textbooks

7.03 Genetics
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Biology (GIR)
Units: 4-0-8
URL: https://biology.mit.edu/course_listings_undergraduate/703_genetics
Lecture: MWF11 (34-101) Recitation: M1 (26-310) or M2 (26-310) or M3 (36-155) or T10 (34-303) or T11 (34-303) or T2 (56-169) or M12 (56-191) or T12 (8-205) +final
______
The principles of genetics with application to the study of biological function at the level of molecules, cells, and multicellular organisms, including humans. Structure and function of genes, chromosomes, and genomes. Biological variation resulting from recombination, mutation, and selection. Population genetics. Use of genetic methods to analyze protein function, gene regulation, and inherited disease.
Fall:G. Fink, P. Gupta, P. Reddien
Spring:M. Hemann, A. Regev
Textbooks (Fall 2016)

7.05 General Biochemistry
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: 5.12, Biology (GIR), or permission of instructor
Units: 5-0-7
Credit cannot also be received for5.07,20.507
______
Contributions of biochemistry toward an understanding of the structure and functioning of organisms, tissues, and cells. Chemistry and functions of constituents of cells and tissues and the chemical and physical-chemical basis for the structures of nucleic acids, proteins, and carbohydrates. Basic enzymology and biochemical reaction mechanisms involved in macromolecular synthesis and degradation, signaling, transport, and movement. General metabolism of carbohydrates, fats, and nitrogen-containing materials such as amino acids, proteins, and related compounds.
M. Vander Heiden, M. Yaffe

7.06 Cell Biology
______

Undergrad (Fall, Spring)
Prereq: 7.03, 7.05
Units: 4-0-8
Lecture: MW9.30-11 (2-190) Recitation: F10 (26-204) or F11 (26-204) or F12 (26-204) or F1 (26-204) +final
______
Presents the biology of cells of higher organisms. Studies the structure, function, and biosynthesis of cellular membranes and organelles; cell growth and oncogenic transformation; transport, receptors, and cell signaling; the cytoskeleton, the extracellular matrix, and cell movements; cell division and cell cycle; functions of specialized cell types. Emphasizes the current molecular knowledge of cell biological processes as well as the genetic, biochemical, and other experimental approaches that resulted in these discoveries.
A. Martin, F. Solomon
Textbooks (Fall 2016)

7.08[J] Biological Chemistry II
______

Undergrad (Spring)
(Same subject as5.08[J])
(Subject meets with7.80)
Prereq: 5.12; 5.07 or 7.05
Units: 4-0-8
______
More advanced treatment of biochemical mechanisms that underlie biological processes. Topics include macromolecular machines such as the ribosome, the proteosome, fatty acid synthases as a paradigm for polyketide synthases and non-ribosomal polypeptide synthases, and polymerases. Emphasis is on experimental methods used to unravel these processes and how these processes fit into the cellular context and coordinate regulation.
E. Nolan

7.09 Quantitative and Computational Biology
______

Undergrad (Spring)
Prereq: 7.03, 7.05
Units: 3-0-9
______
Quantitative and computational analysis of biological systems at the molecular and cellular level. Includes models of biological processes across different time scales, from steady-state to kinetics of gene expression, circadian clock, cell growth, and evolutionary dynamics. Methods include physical, systems, and synthetic biology. Also covers second-generation sequencing technologies, and topics in computational analysis of genomes, including sequence alignment, motif finding, information theory and RNA secondary structure prediction.
C. Burge, G. W. Li

7.102 Laboratory in Molecular Biology
(New)
______

Undergrad (IAP) 1/2 Institute Lab
Prereq: None
Units: 0-5-1
______
Introduces basic methods of experimental molecular biology. Specific experiments vary from year-to-year, but will focus on the molecular genetic characterization of fundamental biological processes. Biology GIR or Chemistry GIR recommended. Limited to 30.
M. Sassanfar, D. Kim

7.11 Biology Teaching
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
For qualified undergraduate students interested in gaining some experience in teaching. Laboratory, tutorial, or classroom teaching under the supervision of a faculty member. Students selected by interview.
Consult Biology Education Office
No required or recommended textbooks

7.15 Experimental Molecular Genetics
______

Undergrad (Spring)
Prereq: 7.02, 7.03
Units: 4-16-10
______
In this project-based laboratory subject, students carry out independent molecular genetics experiments that develop skills in the planning, execution, and analysis of original experimental biological research. Specific research topic, which is determined by teaching staff, involves the application of modern biological methods, such as next-generation sequencing and metabolomics. Reading and writing assignments focus on the critical evaluation and discussion of relevant scientific literature. Emphasizes instruction in laboratory methods and the testing of hypotheses, as well as the critical analysis of experimental results.
J. Weng

7.18 Topics in Experimental Biology
______

Undergrad (Fall, Spring)
(Subject meets with7.19)
Prereq: 7.02, 7.03, 7.05
Units: 4-16-10
URL: https://biology.mit.edu/undergraduate/course_listings/project_labs/718_topics_experimental_biology
Lecture: TR2-4 (68-121) Lab: TBA
______
Independent experimental study under the direction of a member of the Biology Department faculty. Allows students with a strong interest in independent research to fulfill the project laboratory requirement for the Biology Department Program in the context of a research laboratory at MIT. The research must be conducted on the MIT campus and be a continuation of a previous 12-unit UROP project or full-time work over the summer. Written and oral presentation of the research results is required. Journal club discussions are used to help students evaluate and write scientific papers. Instruction and practice in written and oral communication is provided. Permission of the faculty research supervisor and the Biology Education Office must be obtained in advance.
Fall:D. Kim, A.J. Sinskey, C. Kaiser
Spring:D. Kim, C. Kaiser, U. Rajbhandary
No required or recommended textbooks

7.19 Communication in Experimental Biology
______

Undergrad (Fall, Spring)
(Subject meets with7.18)
Prereq: 7.02, 7.03, 7.05
Units: 4-4-4
URL: https://biology.mit.edu/undergraduate/course_listings/project_labs/718_topics_experimental_biology
Lecture: TR2-4 (68-121) Lab: TBA
______
Students carry out independent literature research. Meets with the seminar and writing tutorial portions of 7.18. Journal club discussions are used to help students evaluate and write scientific papers. Instruction and practice in written and oral communication is provided. Permission of the instructor and the Biology Education Office must be obtained in advance.
Fall:D. Kim, A.J. Sinskey, C. Kaiser
Spring:D. Kim, C. Kaiser, U. Rajbhandary
No required or recommended textbooks

7.20[J] Human Physiology
______

Undergrad (Fall)
(Same subject asHST.540[J])
Prereq: 7.05
Units: 5-0-7
Lecture: TR9-11 (E25-111) Recitation: T EVE (7.30 PM) (66-168) or W11 (66-168) +final
______
Comprehensive exploration of human physiology, emphasizing the molecular basis and applied aspects of organ function and regulation in health and disease. Includes a review of cell structure and function, as well as the mechanisms by which the endocrine and nervous systems integrate cellular metabolism. Special emphasis on examining the cardiovascular, pulmonary, gastrointestinal, and renal systems, as well as liver function, drug metabolism, and pharmacogenetics.
M. Krieger, D. Sabatini
Textbooks (Fall 2016)

7.21 Microbial Physiology
______

Undergrad (Fall)
(Subject meets with7.62)
Prereq: 7.03, 7.05
Units: 4-0-8
Lecture: MW11-1 (56-114) Recitation: F1 (26-314)
______
Biochemical properties of bacteria and other microorganisms that enable them to grow under a variety of conditions. Interaction between bacteria and bacteriophages. Genetic and metabolic regulation of enzyme action and enzyme formation. Structure and function of components of the bacterial cell envelope. Protein secretion with a special emphasis on its various roles in pathogenesis. Additional topics include bioenergetics, symbiosis, quorum sensing, global responses to DNA damage, and biofilms. Students taking the graduate version are expected to explore the subject in greater depth.
G. C. Walker, A. J. Sinskey
Textbooks (Fall 2016)

7.22 Developmental Biology
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 7.06
Units: 5-0-7

______
Topics include development of animal body plans, tissue patterning, cell type determination, organogenesis, morphogenesis, stem cells, and the evolution of developmental diversity and processes. Covers experimental approaches to problems of development and evolution, such as the study of vertebrate (mouse, chick, frog, fish) and invertebrate (fly, worm) models.
R. O. Hynes, P. Reddien
Textbooks (Fall 2016)

7.23 Immunology
______

Undergrad (Fall)
(Subject meets with7.63)
Prereq: 7.06
Units: 5-0-7
Lecture: MW1-3 (56-154) Recitation: T12 (56-180) or W EVE (7 PM) (66-154) +final
______
Comprehensive survey of molecular, genetic, and cellular aspects of the immune system. Topics include innate and adaptive immunity; cells and organs of the immune system; immunoglobulin, T cell receptor, and major histocompatibility complex (MHC) proteins and genes; development and functions of B and T lymphocytes; immune responses to infections and tumors; hypersensitivity, autoimmunity, and immunodeficiencies. Particular attention to the development and function of the immune system as a whole, as studied by modern methods and techniques. Students taking the graduate version are expected to explore the subject in greater depth.
H. Ploegh, L. Steiner
Textbooks (Fall 2016)

7.26 Molecular Basis of Infectious Disease
______

Undergrad (Spring)
(Subject meets with7.66)
Prereq: 7.06
Units: 4-0-8
______
Focuses on the principles of host-pathogen interactions with an emphasis on infectious diseases of humans. Presents key concepts of pathogenesis through the study of various human pathogens. Includes critical analysis and discussion of assigned readings. Students taking the graduate version are expected to explore the subject in greater depth.
D. Kim

7.27 Principles of Human Disease
______

Undergrad (Spring)
Prereq: 7.06
Units: 4-0-8
______
Covers current understanding of and modern approaches to human disease, emphasizing the molecular and cellular basis of both genetic disease and cancer. Topics include the genetics of simple and complex traits; karyotypic analysis and positional cloning; genetic diagnosis; the roles of oncogenes and tumor suppressors in tumor initiation, progression, and treatment; the interaction between genetics and environment; animal models of human disease; cancer; aging and disease; and conventional and gene therapy treatment strategies.
D. Housman, L. Guarente

7.28 Molecular Biology
______

Undergrad (Spring)
(Subject meets with7.58)
Prereq: 7.03;Coreq: 7.05
Units: 5-0-7
______
Detailed analysis of the biochemical mechanisms that control the maintenance, expression, and evolution of prokaryotic and eukaryotic genomes. Topics covered in lecture and readings of relevant literature include: gene regulation, DNA replication, genetic recombination, and mRNA translation. Logic of experimental design and data analysis emphasized. Presentations include both lectures and group discussions of representative papers from the literature. Students taking the graduate version are expected to explore the subject in greater depth.
S. Bell

7.29[J] Cellular and Molecular Neurobiology
______

Undergrad (Spring)
(Same subject as9.09[J])
Prereq: 7.05 or 9.01
Units: 4-0-8
______
Introduction to the structure and function of the nervous system. Emphasizes the cellular properties of neurons and other excitable cells. Includes the structure and biophysical properties of excitable cells, synaptic transmission, neurochemistry, neurodevelopment, integration of information in simple systems, and detection and information coding during sensory transduction.
T. Littleton, M. Heiman

7.30A[J] Fundamentals of Ecology I
______

Undergrad (Fall); first half of term
(Same subject as1.018A[J],12.031A[J])
Prereq: None
Units: 2-0-4
Ends Oct 21. Lecture: TR11-12.30 (48-316) Recitation: M4 (48-316) or R4 (48-308)
______
Fundamentals of ecology, considering Earth as an integrated dynamic living system. Coevolution of the biosphere and geosphere, biogeochemical cycles, metabolic diversity, primary productivity, competition and the niche, trophic dynamics and food webs, population growth and limiting factors. Combination of 1.018A and 1.018B counts as REST subject.
O. Cordero, M. Follows
No required or recommended textbooks

7.30B[J] Fundamentals of Ecology II
______

Undergrad (Fall); second half of term
(Same subject as1.018B[J],12.031B[J])
Prereq: 1.018A
Units: 2-0-4
Begins Oct 24. Lecture: TR11-12.30 (48-316) Recitation: M4 (48-316) or R4 (48-308) +final
______
Advanced topics in Ecology. Population modeling, global carbon cycle, climate change, geoengineering, theories of resource competition and mutualism, allometric scaling, ecological genomics, niche theory, human population growth. Applied ecology. Combination of 1.018A and 1.018B counts as REST subject.
O. Cordero, M. Follows
No required or recommended textbooks

7.31 Current Topics in Mammalian Biology: Medical Implications
______

Undergrad (Fall)
Prereq: 7.06 or permission of instructor
Units: 4-0-8
Lecture: M3,W3-5 (68-121) +final
______
Covers recent advances in mammalian cell and developmental biology with particular emphasis on approaches that utilize mouse genetics. Combines formal lectures on selected topics with readings of original papers which are discussed in class. Major emphasis on the implications of mechanisms of human genetic diseases. Topics include early mammalian development; genomic imprinting; X inactivation; embryonic stem cells; nuclear reprogramming of somatic cells; cell migration; nervous system development; and central nervous system degenerative diseases such as Alzheimer's and Huntington's disease. Limited to 20.
F. Gertler, R. Jaenisch
No required or recommended textbooks

7.32 Systems Biology
______

Undergrad (Fall)
(Subject meets with7.81[J],8.591[J])
Prereq: 18.03, 18.05; or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (4-159) Recitation: TBA +final
______
Introduction to cellular and population-level systems biology with an emphasis on synthetic biology, modeling of genetic networks, cell-cell interactions, and evolutionary dynamics. Cellular systems include genetic switches and oscillators, network motifs, genetic network evolution, and cellular decision-making. Population-level systems include models of pattern formation, cell-cell communications, and evolutionary systems biology. Students taking graduate version explore the subject in more depth.
J. Gore
Textbooks (Fall 2016)

7.33[J] Evolutionary Biology: Concepts, Models and Computation
______

Undergrad (Spring)
(Same subject as6.049[J])
Prereq: 7.03; 6.0001 or permission of instructor
Units: 3-0-9
______
Explores and illustrates how evolution explains biology, with an emphasis on computational model building for analyzing evolutionary data. Covers key concepts of biological evolution, including adaptive evolution, neutral evolution, evolution of sex, genomic conflict, speciation, phylogeny and comparative methods, life's history, coevolution, human evolution, and evolution of disease.
R. Berwick, D. Bartel

7.331[J] Infections and Inequalities: Interdisciplinary Perspectives on Global Health
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Social Sciences
(Same subject as21A.331[J],HST.431[J])
Prereq: None
Units: 3-0-9
______
Examines case studies in infectious disease outbreaks to demonstrate how human health is a product of multiple determinants, such as biology, sociocultural and historical factors, politics, economic processes, and the environment. Analyzes how structural inequalities render certain populations vulnerable to illness and explores the moral and ethical dimensions of public health and clinical interventions to promote health. Limited to 25.
E. James, D. Kim, A. Chakraborty

7.340-7.344 Advanced Undergraduate Seminar
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: 7.06 or 7.28
Units: 2-0-4 [P/D/F]
7.340: URL: https://biology.mit.edu/undergraduate/course_listings/advanced_undergraduate_seminars
7.344: URL: https://biology.mit.edu/undergraduate/course_listings/advanced_undergraduate_seminars
7.340: TBA.
7.341: TBA.
7.342: Lecture: W1-3 (4-146)
7.343: Lecture: W EVE (7-9 PM) (56-167)
7.344: Lecture: W1-3 (68-150)
______
Seminars covering topics of current interest in biology with a focus on how to understand experimental methods and design and how to critically read the primary research literature. Small class size facilitates discussions and interactions with an active research scientist. Students visit research laboratories to see firsthand how biological research is conducted. Contact Biology Education Office for topics.
H. R. Horvitz
7.340: No required or recommended textbooks
7.341: No textbook information available
7.342: No required or recommended textbooks
7.343: No required or recommended textbooks
7.344: No required or recommended textbooks

7.345-7.349 Advanced Undergraduate Seminar
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: 7.06 or 7.28
Units: 2-0-4 [P/D/F]
7.349: URL: https://biology.mit.edu/undergraduate/course_listings/advanced_undergraduate_seminars
7.345: Lecture: T3-5 (68-150)
7.346: Lecture: R11-1 (68-150)
Subject Cancelled 7.347 Cancelled
7.348: Lecture: R3-5 (68-150)
7.349: TBA.
______
Seminars covering topics of current interest in biology with a focus on how to understand experimental methods and design and how to critically read the primary research literature. Small class size facilitates discussions and interactions with an active research scientist. Students visit research laboratories to see firsthand how biological research is conducted. Contact Biology Education Office for topics.
H. R. Horvitz
7.345: No required or recommended textbooks
7.346: No required or recommended textbooks
7.348: No textbook information available
7.349: No textbook information available

7.37[J] Molecular and Engineering Aspects of Biotechnology
______

Undergrad (Spring)
(Same subject as10.441[J],20.361[J])
Prereq: 2.005, 3.012, 5.60, or 20.110; 7.06; or permission of instructor
Units: 4-0-8
Credit cannot also be received for7.371
URL: http://web.mit.edu/7.37j/
______
Covers biological and bioengineering principles underlying the development and therapeutic use of recombinant proteins and stem cells; glycoengineering of recombinant proteins; normal and pathological signaling by growth factors and their receptors; receptor trafficking; monoclonal antibodies as therapeutics; protein pharmacology and delivery; stem cell-derived tissues as therapeutics; RNA therapeutics; combinatorial protein engineering; and new antitumor drugs.
H. Lodish, L. Griffith

7.371 Biological and Engineering Principles Underlying Novel Biotherapeutics
______

Undergrad (Fall)
Prereq: 7.06
Units: 4-0-8
Credit cannot also be received for7.37,10.441,20.361
Lecture: MW3-5 (Whitehead-7TH)
______
Covers biological and bioengineering principles underlying the development and therapeutic use of recombinant proteins and immune cells. Special attention to monoclonal antibodies and engineered immune system cells as therapeutics; protein- and glyco- engineering to enhance protein function; protein pharmacology and delivery; nucleic acid- based biotherapeutics; generation of functional cells and tissues from embryonic stem cells and iPS cells; and immune cell-cancer cell interactions in cancer immunotherapy.
J. Chen, H. Lodish
Textbooks (Fall 2016)

7.38 Mechanical Cell Biology
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with7.83)
Prereq: 7.06
Units: 3-0-9
URL: http://web.mit.edu/2.75/
______
Covers current topics in eukaryotic cell biology, with a focus on understanding how physical forces are generated in cells and how these forces organize and shape cells and tissues. Combines lectures and the analysis of the primary literature to explore concepts and experimental approaches related to forces in cell biology at the molecular, cellular, and organismal level. Also considers the journal publication process, providing insights and experience into writing a cover letter, paper submission, reviewer critique, and communicating the significance of one's research. Students taking the graduate version explore the subject in greater depth.
I. Cheeseman, A. Martin

7.41 Principles of Chemical Biology
______

Undergrad (Spring)
(Subject meets with7.73)
Prereq: 7.05
Units: 3-0-9
______
Spanning the fields of biology, chemistry and engineering, class addresses the principles of chemical biology and its application of chemical and physical methods and reagents to the study and manipulation of biological systems. Topics include bioorthogonal reactions and activity-based protein profiling, small molecule inhibitors and chemical genetics, fluorescent probes for biological studies, and unnatural amino acid mutagenesis. Also covers chemical biology approaches for studying dynamic post-translational modification reactions, natural product biosynthesis and mutasynthesis, and high-throughput drug screening. Students taking the graduate version are expected to explore the subject in greater depth
B. Imperiali, J. K. Weng

7.45 The Hallmarks of Cancer
______

Undergrad (Fall)
(Subject meets with7.85)
Prereq: None.Coreq: 7.06
Units: 4-0-8
Lecture: TR1-2.30 (56-114) Recitation: R EVE (7 PM) (56-167) or F11 (4-144) or F12 (4-144) +final
______
Provides a comprehensive introduction to the fundamentals of cancer biology and cancer treatment. Topics include cancer genetics, genomics, and epigenetics; familial cancer syndromes; signal transduction, cell cycle control, and apoptosis; cancer metabolism; stem cells and cancer; metastasis; cancer immunology and immunotherapy; conventional and molecularly-targeted therapies; and early detection and prevention. Students taking graduate version complete additional assignments.
T. Jacks, M. Vander Heiden
Textbooks (Fall 2016)

7.458[J] Advances in Biomanufacturing
(New)
______

Undergrad (Fall, Spring); second half of term
(Same subject as10.03[J])
(Subject meets with7.548[J],10.53[J])
Prereq: None
Units: 1-0-2 [P/D/F]
Begins Oct 24. Lecture: TR11 (66-148)
______
Seminar examines how biopharmaceuticals, an increasingly important class of pharmaceuticals, are manufactured. Topics range from fundamental bioprocesses to new technologies to the economics of biomanufacturing. Also covers the impact of globalization on regulation and quality approaches as well as supply chain integrity. Students taking graduate version complete additional assignments.
J. C. Love, A. Sinskey, S. Springs
No textbook information available

7.49[J] Developmental Neurobiology
______

Undergrad (Spring)
(Same subject as9.18[J])
(Subject meets with7.69[J],9.181[J])
Prereq: 9.01, 7.03, 7.05, or permission of instructor
Units: 3-0-9
______
Considers molecular control of neural specification, formation of neuronal connections, construction of neural systems, and the contributions of experience to shaping brain structure and function. Topics include: neural induction and pattern formation, cell lineage and fate determination, neuronal migration, axon guidance, synapse formation and stabilization, activity-dependent development and critical periods, development of behavior. Students taking graduate version complete additional readings that will be addressed in their mid-term and final exams.
E. Nedivi, M. Heiman

7.391 Independent Study in Biology
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

7.392 Independent Study in Biology
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No required or recommended textbooks

7.393 Independent Study in Genetics
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No required or recommended textbooks

7.394 Independent Study in Biochemistry
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No required or recommended textbooks

7.395 Independent Study in Cell and Molecular Biology
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No required or recommended textbooks

7.396 Independent Study in Experimental Biology
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Program of study or research to be arranged with a department faculty member.
Staff
No required or recommended textbooks

7.S390 Special Subject in Biology
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

7.S391 Special Subject in Biology
______

Undergrad (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

7.S392 Special Subject in Biology
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff

7.S399 Special Subject in Biology
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff

7.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of department.
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

7.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of department
Units arranged
TBA.
______
Undergraduate research opportunities in the Department of Biology. For further information, consult departmental coordinator, Gene Brown.
Staff
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

Graduate Subjects

MIT-WHOI Joint Program in Oceanography

7.410 Applied Statistics
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
Provides an introduction to modern applied statistics. Topics include likelihood-based methods for estimation, confidence intervals, and hypothesis-testing; bootstrapping; time series modeling; linear models; nonparametric regression; and model selection. Organized around examples drawn from the recent literature.
A. Solow

7.411 Seminars in Biological Oceanography
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
Meets at WHOI. TBA.
______
Selected topics in biological oceanography.
WHOI Staff
No textbook information available

7.421 Problems in Biological Oceanography
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
Meets at WHOI. TBA.
______
Advanced problems in biological oceanography with assigned reading and consultation.
Information: M. Neubert (WHOI)
No textbook information available

7.430 Topics in Quantitative Marine Science
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussions on quantitative marine ecology. Topics vary from year to year.
WHOI Staff
No textbook information available

7.431 Topics in Marine Ecology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussions on ecological principles and processes in marine populations, communities, and ecosystems. Topics vary from year to year.
WHOI Staff
No textbook information available

7.432 Topics in Marine Physiology and Biochemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussions on physiological and biochemical processes in marine organisms. Topics vary from year to year.
WHOI Staff
No textbook information available

7.433 Topics in Biological Oceanography
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussions on biological oceanography. Topics vary from year to year.
WHOI Staff
No textbook information available

7.434 Topics in Zooplankton Biology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussions on the biology of marine zooplankton. Topics vary from year to year.
WHOI Staff
No textbook information available

7.435 Topics in Benthic Biology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussions on the biology of marine benthos. Topics vary from year to year.
WHOI Staff
No textbook information available

7.436 Topics in Phytoplankton Biology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussion on the biology of marine phytoplankton. Topics vary from year to year.
WHOI Staff
No textbook information available

7.437 Topics in Molecular Biological Oceanography
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussion on molecular biological oceanography. Topics vary from year to year.
WHOI Staff
No textbook information available

7.438 Topics in the Behavior of Marine Animals
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussion on the behavioral biology of marine animals. Topics vary from year to year.
WHOI Staff
No textbook information available

7.439 Topics in Marine Microbiology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussion on the biology of marine prokaryotes. Topics vary from year to year.
WHOI Staff
No textbook information available

7.440 An Introduction to Mathematical Ecology
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Calculus I (GIR), 7.30B, or permission of instructor
Units: 3-0-9
______
Covers the basic models of population growth, demography, population interaction (competition, predation, mutualism), food webs, harvesting, and infectious disease, and the mathematical tools required for their analysis. Because these tools are also basic to the analysis of models in biochemistry, physiology, and behavior, subject also broadly relevant to students whose interests are not limited to ecological problems.
M. Neubert, H. Caswell (WHOI)

7.470 Biological Oceanography
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Intended for students with advanced training in biology. Intensive overview of biological oceanography. Major paradigms discussed, and dependence of biological processes in the ocean on physical and chemical aspects of the environment examined. Surveys the diversity of marine habitats, major groups of taxa inhabiting those habitats, and the general biology of the various taxa: the production and consumption of organic material in the ocean, as well as factors controlling those processes. Species diversity, structure of marine food webs, and the flow of energy within different marine habitats are detailed and contrasted.
WHOI Staff

7.491 Research in Biological Oceanography
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
Meets at WHOI. TBA.
______
Directed research in biological oceanography not leading to graduate thesis and initiated prior to the qualifying exam.
WHOI Staff
No textbook information available

Microbiology (MICRO)

7.492[J] Methods and Problems in Microbiology
______

Graduate (Fall)
(Same subject as1.86[J],20.445[J])
Prereq: None
Units: 3-0-9
Lecture: W EVE (3-6 PM) (4-146)
______
Students will read and discuss primary literature covering key areas of microbial research with emphasis on methods and approaches used to understand and manipulate microbes. Preference to first-year Microbiology and Biology students.
M. Laub
No required or recommended textbooks

7.493[J] Microbial Genetics and Evolution
______

Graduate (Fall)
(Same subject as1.87[J],12.493[J],20.446[J])
Prereq: 7.03, 7.05, or permission of instructor
Units: 4-0-8
Lecture: TR12.30-2.30 (66-160)
______
Covers aspects of microbial genetic and genomic analyses, central dogma, horizontal gene transfer, and evolution.
A. D. Grossman, G. Fournier
Textbooks (Fall 2016)

7.494 Research Problems in Microbiology
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Directed research in the fields of microbial science and engineering.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

7.498 Teaching Experience in Microbiology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
For qualified graduate students in the Microbiology graduate program interested in teaching. Classroom or laboratory teaching under the supervision of a faculty member.
Staff
No required or recommended textbooks

7.499 Research Rotations in Microbiology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor;Coreq: 7.492, or 7.493
Units arranged [P/D/F]
TBA.
______
Introduces students to faculty participating in the interdepartmental Microbiology graduate program through a series of three lab rotations, which provide broad exposure to microbiology research at MIT. Students select a lab for thesis research by the end of their first year. Given the interdisciplinary nature of the program and the many research programs available, students may be able to work jointly with more than one research supervisor. Limited to students in the Microbiology graduate program.
Staff
No required or recommended textbooks

7.MTHG Microbiology Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of a PhD thesis. To be arranged by the student and the appropriate MIT faculty member.
Staff
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

Biology

7.50 Method and Logic in Molecular Biology
______

Graduate (Fall)
Prereq: Permission of instructor orCoreq: 7.51, 7.52
Units: 4-0-8
1st mtg Sept 8 at 2.30 pm. Recitation: M3-6,R2.30-5.30 (68-180, 68-156, Whitehead-7TH)
______
Logic, experimental design and methods in biology, using discussions of the primary literature to discern the principles of biological investigation in making discoveries and testing hypotheses. In collaboration with faculty, students also apply those principles to generate a potential research project, presented in both written and oral form. Limited to Course 7 graduate students.
Staff
No required or recommended textbooks

7.51 Principles of Biochemical Analysis
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 6-0-6
Friday recitation in 66-168. Lecture: MWF9-10.30 (56-114) Recitation: T2.30,F1 (66-144)
______
Principles of biochemistry, emphasizing structure, equilibrium studies, kinetics, informatics, single-molecule studies, and experimental design. Topics include macromolecular binding and specificity, protein folding and unfolding, allosteric systems, transcription factors, kinases, membrane channels and transporters, and molecular machines.
A. Keating, R. T. Sauer
No required or recommended textbooks

7.52 Genetics for Graduate Students
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 4-0-8
Lecture: TR9.30-11.30 (56-154) Recitation: W3.30 (26-314) or F2.30 (26-210)
______
Principles and approaches of genetic analysis, including Mendelian inheritance and prokaryotic genetics, yeast genetics, developmental genetics, neurogenetics, and human genetics.
A. Amon, D. Housman, H. R. Horvitz
Textbooks (Fall 2016)

7.540[J] Frontiers in Chemical Biology
______

Graduate (Fall)
(Same subject as5.54[J],20.554[J])
Prereq: 5.13, 5.07, 7.06, permission of instructor
Units: 2-0-4
Lecture: R8.30-10 (4-231)
______
Introduction to current research at the interface of chemistry, biology, and bioengineering. Topics include imaging of biological processes, metabolic pathway engineering, protein engineering, mechanisms of DNA damage, RNA structure and function, macromolecular machines, protein misfolding and disease, metabolomics, and methods for analyzing signaling network dynamics. Lectures are interspersed with class discussions and student presentations based on current literature.
M. Shoulders
No textbook information available

7.547[J] Principles and Practice of Drug Development
______

Graduate (Fall)
(Same subject as10.547[J],15.136[J],HST.920[J],IDS.620[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://hst-hu-mit.mit.edu/courses/HST920
Lecture: W EVE (3-6 PM) (1-190)
______
Description and critical assessment of the major issues and stages of developing a pharmaceutical or biopharmaceutical. Drug discovery, preclinical development, clinical investigation, manufacturing and regulatory issues considered for small and large molecules. Economic and financial considerations of the drug development process. Multidisciplinary perspective from faculty in clinical; life; and management sciences; as well as industry guests.
T. J. Allen, C. L. Cooney, S. N. Finkelstein, A. J. Sinskey, G. K. Raju
No textbook information available

7.548[J] Advances in Biomanufacturing
(New)
______

Graduate (Fall, Spring); second half of term
(Same subject as10.53[J])
(Subject meets with 7.458[J],10.03[J])
Prereq: None
Units: 1-0-2
Begins Oct 24. Lecture: TR11 (66-148)
______
Seminar examines how biopharmaceuticals, an increasingly important class of pharmaceuticals, are manufactured. Topics range from fundamental bioprocesses to new technologies to the economics of biomanufacturing. Also covers the impact of globalization on regulation and quality approaches as well as supply chain integrity. Students taking graduate version complete additional assignments.
J. C. Love, A. Sinskey, S. Springs
No textbook information available

7.549[J] Case Studies and Strategies in Drug Discovery and Development
______

Graduate (Spring)
(Same subject as15.137[J],20.486[J],HST.916[J])
Prereq: None
Units: 2-0-4
URL: http://mit.edu/7.549j
______
Aims to develop appreciation for the stages of drug discovery and development, from target identification, to the submission of preclinical and clinical data to regulatory authorities for marketing approval. Following introductory lectures on the process of drug development, students working in small teams analyze how one of four new drugs or drug candidates traversed the discovery/development landscape. For each case, an outside expert from the sponsoring drug company or pivotal clinical trial principal investigator provides guidance and critiques the teams' presentations to the class.
S. R. Tannenbaum, A. J. Sinskey, A. W. Wood

7.55 Case Studies in Modern Experimental Design
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 2-0-7
______
Focuses on enhancing students' ability to analyze, design and present experiments, emphasizing modern techniques. Class discussions begin with papers that developed or utilized contemporary approaches (e.g., quantitative microscopy, biophysical and molecular genetic methods) to address important problems in biology. Each student prepares one specific aim of a standard research proposal for a project that emphasizes research strategy, experimental design, and writing.
L. Guarente, F. Solomon

7.57 Quantitative Biology for Graduate Students
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 4-0-8
______
Introduces the fundamental concepts and tools of quantitative approaches to molecular and cellular biology. Covers a wide range of mathematical, computational, and statistical methods, although no previous expertise in these areas is required. Focuses on understanding quantitative approaches through the analysis of particular problems and examples drawn from classical genetics, molecular biology, cell biology, genomics, and systems biology.
P. Gupta, A. Regev

7.58 Molecular Biology
______

Graduate (Spring)
(Subject meets with7.28)
Prereq: 7.03, 7.05, permission of instructor
Units: 5-0-7
______
Detailed analysis of the biochemical mechanisms that control the maintenance, expression, and evolution of prokaryotic and eukaryotic genomes. Topics covered in lecture and readings of relevant literature include: gene regulation, DNA replication, genetic recombination, and mRNA translation. Logic of experimental design and data analysis emphasized. Presentations include both lectures and group discussions of representative papers from the literature. Students taking the graduate version are expected to explore the subject in greater depth.
S. Bell

7.59[J] Teaching College-Level Science and Engineering
______

Graduate (Fall)
(Same subject as1.95[J],5.95[J],8.395[J],18.094[J])
(Subject meets with2.978)
Prereq: None
Units: 2-0-2 [P/D/F]
URL: https://wikis.mit.edu/confluence/pages/viewpage.action?pageId=110876412
Lecture: R9-11 (4-149)
______
Participatory seminar focuses on the knowledge and skills necessary for teaching science and engineering in higher education. Topics include theories of adult learning; course development; promoting active learning, problemsolving, and critical thinking in students; communicating with a diverse student body; using educational technology to further learning; lecturing; creating effective tests and assignments; and assessment and evaluation. Students research and present a relevant topic of particular interest. Appropriate for both novices and those with teaching experience.
J. Rankin
No textbook information available

7.60 Cell Biology: Structure and Functions of the Nucleus
______

Graduate (Spring)
Prereq: 7.06
Units: 4-0-8
______
Eukaryotic genome structure, function, and expression, processing of RNA, and regulation of the cell cycle. Emphasis on the techniques and logic used to address important problems in nuclear cell biology. Lectures on broad topic areas in nuclear cell biology and discussions on representative recent papers.
R. Young, L. Boyer

7.61 Eukaryotic Cell Biology: Principles and Practice
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 4-0-8
Lecture: MW1-3 (E25-117) +final
______
Emphasizes methods and logic used to analyze structure and function of eukaryotic cells in diverse systems (e.g., yeast, fly, worm, mouse, human; development, stem cells, neurons). Combines lectures and in-depth roundtable discussions of literature readings with the active participation of faculty experts. Focuses on membranes (structure, function, traffic), organelles, the cell surface, signal transduction, cytoskeleton, cell motility and extracellular matrix. Ranges from basic studies to applications to human disease, while stressing critical analysis of experimental approaches. Enrollment limited.
R. O. Hynes, M. Krieger
Textbooks (Fall 2016)

7.62 Microbial Physiology
______

Graduate (Fall)
(Subject meets with7.21)
Prereq: 7.03, 7.05, permission of instructor
Units: 4-0-8
Lecture: MW11-1 (56-114) Recitation: F1 (26-314)
______
Biochemical properties of bacteria and other microorganisms that enable them to grow under a variety of conditions. Interaction between bacteria and bacteriophages. Genetic and metabolic regulation of enzyme action and enzyme formation. Structure and function of components of the bacterial cell envelope. Protein secretion with a special emphasis on its various roles in pathogenesis. Additional topics include bioenergetics, symbiosis, quorum sensing, global responses to DNA damage, and biofilms. Students taking the graduate version are expected to explore the subject in greater depth.
G. C. Walker, A. J. Sinskey
Textbooks (Fall 2016)

7.63 Immunology
______

Graduate (Fall)
(Subject meets with7.23)
Prereq: 7.06, permission of instructor
Units: 5-0-7
Lecture: MW1-3 (56-154) +final
______
Comprehensive survey of molecular, genetic, and cellular aspects of the immune system. Topics include innate and adaptive immunity; cells and organs of the immune system; immunoglobulin, T cell receptor, and major histocompatibility complex (MHC) proteins and genes; development and functions of B and T lymphocytes; immune responses to infections and tumors; hypersensitivity, autoimmunity, and immunodeficiencies. Particular attention to the development and function of the immune system as a whole, as studied by modern methods and techniques. Students taking the graduate version are expected to explore the subject in greater depth.
H. Ploegh, L. Steiner
Textbooks (Fall 2016)

7.64 Molecular Mechanisms, Pathology and Therapy of Human Neuromuscular Disorders
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Investigates the molecular and clinical basis of central nervous system and neuromuscular disorders with particular emphasis on strategies for therapeutic intervention. Considers the in-depth analysis of clinical features, pathological mechanisms, and responses to current therapeutic interventions. Covers neurodegenerative diseases, such as Huntington's disease, Parkinson's disease, Alzheimer's disease, Amyotropic Lateral Schlerosis, Frontal Temporal Dementia, and neuromuscular disorders, such as Myotonic Dystrophy, Facio Scapular Humoral Dystrophy, and Duchenne Muscular Dystrophy.
D. Housman

7.65[J] Molecular and Cellular Neuroscience Core I
______

Graduate (Fall)
(Same subject as9.015[J])
Prereq: None
Units: 3-0-9
Lecture: TR1-2.30 (46-4062)
______
Survey and primary literature review of major topic areas in molecular and cellular neurobiology. Covers neurogenomics, nervous system formation, axonal pathfinding, cytoskeletal regulation, synapse formation, neurotransmitter release, and cellular neurophysiology. Includes lectures and weekly paper write-ups, together with student presentations and discussion of primary literature. A final two-page research write-up is also due at the end of the term.
J. T. Littleton, H. Sive, F. Gertler
No required or recommended textbooks

7.66 Molecular Basis of Infectious Disease
______

Graduate (Spring)
(Subject meets with7.26)
Prereq: 7.06, permission of instructor
Units: 4-0-8
______
Focuses on the principles of host-pathogen interactions with an emphasis on infectious diseases of humans. Presents key concepts of pathogenesis through the study of various human pathogens. Includes critical analysis and discussion of assigned readings. Students taking the graduate version are expected to explore the subject in greater depth.
D. Kim

7.67[J] Genetic Methods in Neurobiology
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as9.322[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://mit.edu/7.67j/
______
Presents selected topics in which genetic analysis informs neurobiological issues, including action potential conduction and synaptic release in Drosophila, axon guidance in nematodes and Drosophila, olfaction and orienting behavior in nematodes. Studies hippocampal and cortical circuitry and function in mice, as well as genetically-determined and genetically-influenced human traits and diseases. Reviews methods such as mutagenesis, gene knockouts and transgene constructs, tissue-specific expression vectors, optically, chemically and thermally-inducible gene activation and inactivation.
W. G. Quinn

7.68[J] Molecular and Cellular Neuroscience Core II
______

Graduate (Spring)
(Same subject as9.013[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Survey and primary literature review of major areas in molecular and cellular neurobiology. Covers genetic neurotrophin signaling, adult neurogenesis, G-protein coupled receptor signaling, glia function, epigenetics, neuronal and homeostatic plasticity, neuromodulators of circuit function, and neurological/psychiatric disease mechanisms. Includes lectures and exams, and involves presentation and discussion of primary literature. 9.015 recommended, though the core subjects can be taken in any sequence.
G. Feng, L.-H. Tsai

7.69[J] Developmental Neurobiology
______

Graduate (Spring)
(Same subject as9.181[J])
(Subject meets with 7.49[J],9.18[J])
Prereq: 9.011 or permission of instructor
Units: 3-0-9
______
Considers molecular control of neural specification, formation of neuronal connections, construction of neural systems, and the contributions of experience to shaping brain structure and function. Topics include: neural induction and pattern formation, cell lineage and fate determination, neuronal migration, axon guidance, synapse formation and stabilization, activity-dependent development and critical periods, development of behavior. In addition to final exam, analysis and presentation of research papers required for final grade. Students taking graduate version complete additional assignments. Students taking graduate version complete additional readings that will be addressed in their mid-term and final exams.
E. Nedivi, M. Heiman

7.70 Regulation of Gene Expression
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 4-0-8
______
Seminar examines basic principles of biological regulation of gene expression. Focuses on examples that underpin these principles, as well as those that challenge certain long-held views. Topics covered may include the role of transcription factors, enhancers, DNA modifications, non-coding RNAs, and chromatin structure in the regulation of gene expression and mechanisms for epigenetic inheritance of transcriptional states. Limited to 40.
L. Boyer, M. Gehring

7.71 Biophysical Chemistry Techniques
______

Graduate (Spring)
(Subject meets with5.78)
Prereq: 5.13, 5.60; 5.07 or 7.05
Units: 5-0-7
URL: http://web.mit.edu/5.78/www/
______
For students who want to understand the benefits and caveats of biophysical techniques used to ascertain the structure of macromolecules, especially on the 3-D level. The first half of the course focuses on x-ray crystallography, the single most important technique used in determining the 3-D structure of macromolecules. Discussion of crystallographic theory is complemented with exercises such as crystallization, data processing, and model building. In the second half of the course, biophysical techniques are covered that supplement the 3-D characterization of biological macromolecules. Topics include CD spectroscopy, isothermal calorimetry, analytical ultracentrifugation, dynamic light scattering, and surface plasmon resonance (BIAcore). Theoretical principles behind the techniques are covered, applications are discussed, and students are performing practical exercises using instrumentation available at MIT. Meets with 5.78 when offered concurrently.
C. Drennan, T. Schwartz

7.72 Principles and Frontiers of Developmental Biology
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 4-0-8
Lecture: MW11-1 (Whitehead-705)
______
Covers fundamental principles and frontiers of animal development. Focuses on molecular mechanisms, experimental approaches, evolutionary context, human disorders, and topics of societal importance. Compares vertebrate (mouse, chick, frog, fish) and invertebrate (fly, worm) models. Modules include patterning and asymmetry of the body plan, cell type determination and diversity, organogenesis, morphogenesis, maternal control, organismal growth, stem cells, tissue engineering, and issues in human development.
H. Sive, T. Orr-Weaver
Textbooks (Fall 2016)

7.73 Principles of Chemical Biology
(New)
______

Graduate (Spring)
(Subject meets with7.41)
Prereq: 7.05; Permission of instructor
Units: 3-0-9
______
Spanning the fields of biology, chemistry and engineering, class addresses the principles of chemical biology and its application of chemical and physical methods and reagents to the study and manipulation of biological systems. Topics include bioorthogonal reactions and activity-based protein profiling, small molecule inhibitors and chemical genetics, fluorescent probes for biological studies, and unnatural amino acid mutagenesis. Also covers chemical biology approaches for studying dynamic post-translational modification reactions, natural product biosynthesis and mutasynthesis, and high-throughput drug screening. Students taking the graduate version are expected to explore the subject in greater depth.
B. Imperiali, J. K. Weng

7.74[J] Topics in Biophysics and Physical Biology
______

Graduate (Fall)
(Same subject as8.590[J],20.416[J])
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: F1-2.30 (56-167)
______
Provides broad exposure to research in biophysics and physical biology, with emphasis on the critical evaluation of scientific literature. Weekly meetings include in-depth discussion of scientific literature led by distinct faculty on active research topics. Each session also includes brief discussion of non-research topics including effective presentation skills, writing papers and fellowship proposals, choosing scientific and technical research topics, time management, and scientific ethics.
I. Cisse, N. Fakhri, M. Guo
No required or recommended textbooks

7.76 Topics in Macromolecular Structure and Function
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
______
In-depth analysis and discussion of classic and current literature, with an emphasis on the structure, function, and mechanisms of proteins and other biological macromolecules.
C. Drennan, R. T. Sauer

7.77 Nucleic Acids, Structure, Function, Evolution and Their Interactions with Proteins
______

Graduate (Spring)
Prereq: 7.05 or 7.51
Units: 3-0-9
______
Surveys primary literature, focusing on biochemical, biophysical, genetic, and combinatorial approaches for understanding nucleic acids. Topics include the general properties, functions, and structural motifs of DNA and RNA; RNAs as catalysts and as regulators of gene expression; RNA editing and surveillance, and the interaction of nucleic acids with proteins, such as zinc-finger proteins, modification enzymes, aminoacyl-tRNA synthetases and other proteins of the translational machinery. Includes some lectures but is mostly analysis and discussion of current literature in the context of student presentations.
D. Bartel, U. RajBhandary

7.80 Biological Chemistry II
______

Graduate (Spring)
(Subject meets with5.08[J],7.08[J])
Prereq: 5.12; 5.07 or 7.05
Units: 4-0-8
______
More advanced treatment of biochemical mechanisms that underlie biological processes. Topics include macromolecular machines such as the ribosome, the proteosome, fatty acid synthases as a paradigm for polyketide synthases and non-ribosomal polypeptide synthases, and polymerases. Emphasis is on experimental methods used to unravel these processes and how these processes fit into the cellular context and coordinate regulation. Students taking the graduate version are expected to explore the subject in greater depth.
J. Stubbe, E. Nolan

7.81[J] Systems Biology
______

Graduate (Fall)
(Same subject as8.591[J])
(Subject meets with7.32)
Prereq: 18.03, 18.05; or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (4-159) Recitation: TBA +final
______
Introduction to cellular and population-level systems biology with an emphasis on synthetic biology, modeling of genetic networks, cell-cell interactions, and evolutionary dynamics. Cellular systems include genetic switches and oscillators, network motifs, genetic network evolution, and cellular decision-making. Population-level systems include models of pattern formation, cell-cell communication, and evolutionary systems biology. Students taking graduate version explore the subject in more depth.
J. Gore
Textbooks (Fall 2016)

7.82 Topics of Mammalian Development and Genetics
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9 [P/D/F]
______
Seminar covering embryologic, molecular, and genetic approaches to development in mice and humans. Topics include preimplantation development; gastrulation; embryonic stem cells, gene targeting and nuclear reprogramming of somatic cells; genomic imprinting; X-inactivation; sex determination; and germ cells.
R. Jaenisch, R. Young

7.83 Mechanical Cell Biology
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with7.38)
Prereq: 7.06, permission of instructor
Units: 3-0-9
______
Covers current topics in eukaryotic cell biology, with a focus on understanding how physical forces are generated in cells and how these forces organize and shape cells and tissues. Combines lectures and the analysis of the primary literature to explore concepts and experimental approaches related to forces in cell biology at the molecular, cellular, and organismal level. Also considers the journal publication process, providing insights and experience into writing a cover letter, paper submission, reviewer critique, and communicating the significance of one's research. Students taking the graduate version explore the subject in greater depth.
I. Cheeseman, A. Martin

7.85 The Hallmarks of Cancer
______

Graduate (Fall)
(Subject meets with7.45)
Prereq: Permission of instructor;Coreq: 7.06
Units: 4-0-8
Lecture: TR1-2.30 (56-114) Recitation: R EVE (7 PM) (56-167) or F11 (4-144) or F12 (4-144) +final
______
Provides a comprehensive introduction to the fundamentals of cancer biology and cancer treatment. Topics include cancer genetics, genomics, and epigenetics; familial cancer syndromes; signal transduction, cell cycle control, and apoptosis; cancer metabolism; stem cells and cancer; metastasis; cancer immunology and immunotherapy; conventional and molecularly-targeted therapies; and early detection and prevention. Students taking graduate version complete additional assignments.
T. Jacks, M. Vander Heiden
Textbooks (Fall 2016)

7.87 Protein Folding and Misfolding in Biology
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 7.51, 7.52; or permission of instructor
Units: 3-0-6
______
Covers protein folding, misfolding, aggregation, and amyloid formation in the context of biological systems. Addresses topics such as chaperone structure and function, biofilm formation by bacteria, protein-folding diseases (including but not limited to Alzheimer's, Parkinson's, and Huntington's diseases), the process of therapeutics discovery for drugs and biologics. Features guest lectures and Skype discussions with international leaders in the field. Students present papers covering mutually agreed-upon topics of interest.
S. Lindquist

7.89[J] Topics in Computational and Systems Biology
______

Graduate (Fall)
(Same subject asCSB.100[J])
Prereq: Permission of instructor
Units: 2-0-10
Lecture: F11-1 (66-148)
______
Seminar based on research literature. Papers covered are selected to illustrate important problems and varied approaches in the field of computational and systems biology, and to provide students a framework from which to evaluate new developments. Preference to first-year CSB PhD students.
C. Burge
No textbook information available

7.931 Independent Study in Biology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

7.932 Independent Study in Biology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of study or research to be arranged with a department faculty member.
Staff
No required or recommended textbooks

7.933 Research Rotations in Biology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Introduces students to faculty participating in the Biology graduate program through a series of lab rotations, which provide broad exposure to biology research at MIT. Students select a lab for thesis research by the end of their first year. Limited to students in the Biology graduate program.
Staff
No required or recommended textbooks

7.934 Teaching Experience in Biology
______

Graduate (Fall, Spring)
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
For qualified graduate students in the Biology graduate program interested in teaching. Classroom or laboratory teaching under the supervision of a faculty member.
Staff
No required or recommended textbooks

7.935 Responsible Conduct in Biology
______

Graduate (Fall)
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Sessions focus on the responsible conduct of science. Considers recordkeeping and reporting; roles of mentor and mentee; authorship, review, and confidentiality; resolving conflicts; misfeasance and malfeasance; collaborations, competing interests, and intellectual property; and proper practices in the use of animal and human subjects. Limited to second-year graduate students in Biology.
Staff
No required or recommended textbooks

7.941 Research Problems
______

Graduate (Fall, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

7.942 Research Problems
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Directed research in a field of biological science, but not contributory to graduate thesis.
Consult Biology Education Office

7.95 Cancer Biology
______

Graduate (Spring)
Prereq: 7.85, permission of instructor
Units: 3-0-9
______
Advanced seminar involving intensive analysis of historical and current developments in cancer biology. Topics address principles of apoptosis, principles of cancer biology, cancer genetics, cancer cell metabolism, tumor immunology, and therapy. Detailed analysis of research literature, including important reports published in recent years. Enrollment limited.
R. Weinberg, O. Yilmaz

7.98[J] Neural Plasticity in Learning and Memory
______

Graduate (Spring)
(Same subject as9.301[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://web.mit.edu/7.98/
______
Examination of the role of neural plasticity during learning and memory of invertebrates and mammals. Detailed critical analysis of the current literature of molecular, cellular, genetic, electrophysiological, and behavioral studies. Student-directed presentations and discussions of original papers supplemented by introductory lectures. Juniors and seniors require instructor's permission.
S. Tonegawa, W. Quinn

7.S930 Special Subject in Biology
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

7.S931 Special Subject in Biology
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

7.S932 Special Subject in Biology
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff

7.S939 Special Subject in Biology
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff

7.THG Graduate Biology Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of a Ph.D. thesis; to be arranged by the student and an appropriate MIT faculty member.
Staff
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|7.00-7.999 plus UROP and Thesis|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 8: Physics
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Course 8: Physics
Fall 2016


Undergraduate Subjects

8.01 Physics I
______

Undergrad (Fall) Physics I
Prereq: None
Units: 3-2-7
Credit cannot also be received for8.011,8.012,8.01L,CC.801,CC.8012,ES.801,ES.8012
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW9-11,F9 (26-152) or MW11-1,F11 (26-152) or MW1-3,F1 (26-152) or MW3-5,F4 (26-152) or TR9-11,F10 (26-152) or TR11-1,F12 (26-152) or TR2-4,F3 (26-152) +final
______
Introduces classical mechanics. Space and time: straight-line kinematics; motion in a plane; forces and static equilibrium; particle dynamics, with force and conservation of momentum; relative inertial frames and non-inertial force; work, potential energy and conservation of energy; kinetic theory and the ideal gas; rigid bodies and rotational dynamics; vibrational motion; conservation of angular momentum; central force motions; fluid mechanics. Subject taught using the TEAL (Technology-Enabled Active Learning) format which features students working in groups of three, discussing concepts, solving problems, and doing table-top experiments with the aid of computer data acquisition and analysis.
D. Chakrabarty, P. Dourmashkin
Textbooks (Fall 2016)

8.011 Physics I
______

Undergrad (Spring) Physics I
Prereq: None
Units: 5-0-7
Credit cannot also be received for8.01,8.012,8.01L,CC.801,CC.8012,ES.801,ES.8012
URL: http://web.mit.edu/physics/subjects/index.html
______
Introduces classical mechanics. Space and time: straight-line kinematics; motion in a plane; forces and equilibrium; experimental basis of Newton's laws; particle dynamics; universal gravitation; collisions and conservation laws; work and potential energy; vibrational motion; conservative forces; inertial forces and non-inertial frames; central force motions; rigid bodies and rotational dynamics. Designed for students with previous experience in 8.01; the subject is designated as 8.01 on the transcript.
Staff

8.012 Physics I
______

Undergrad (Fall) Physics I
Prereq: None
Units: 5-0-7
Credit cannot also be received for8.01,8.011,8.01L,CC.801,CC.8012,ES.801,ES.8012
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR9-10.30 (6-120) Lab: TBA Recitation: MW10 (26-322) or MW11 (26-322) or MW1 (26-314) or MW2 (26-314) +final
______
Elementary mechanics, presented in greater depth than in 8.01. Newton's laws, concepts of momentum, energy, angular momentum, rigid body motion, and non-inertial systems. Uses elementary calculus freely; concurrent registration in a math subject more advanced than 18.01 is recommended. In addition to covering the theoretical subject matter, students complete a small experimental project of their own design. Freshmen admitted via AP or Math Diagnostic for Physics Placement results.
M. Soljacic
Textbooks (Fall 2016)

8.01L Physics I
______

Undergrad (Fall, IAP) Physics I
Prereq: None
Units: 3-2-7
Credit cannot also be received for8.01,8.011,8.012,CC.801,CC.8012,ES.801,ES.8012
URL: http://web.mit.edu/physics/subjects/index.html
Final exam during iap. Lecture: MWF9 (6-120) Recitation: TR10 (32-082) or TR11 (32-082) or TR12 (32-082) or TR1 (32-082) or TR2 (2-135) or TR3 (2-135)
______
Introduction to classical mechanics (see description under 8.01). Includes components of the TEAL (Technology-Enabled Active Learning) format. Material covered over a longer interval so that the subject is completed by the end of the IAP. Substantial emphasis given to reviewing and strengthening necessary mathematics tools, as well as basic physics concepts and problem-solving skills. Content, depth, and difficulty is otherwise identical to that of 8.01. The subject is designated as 8.01 on the transcript.
P. Jarillo-Herrero
Textbooks (Fall 2016)

8.02 Physics II
______

Undergrad (Fall, Spring) Physics II
Prereq: Physics I (GIR), Calculus I (GIR)
Units: 3-2-7
Credit cannot also be received for8.021,8.022,CC.802,CC.8022,ES.802,ES.8022
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW9-11,F9 (32-082) or MW11-1,F11 (32-082) +final
______
Introduction to electromagnetism and electrostatics: electric charge, Coulomb's law, electric structure of matter; conductors and dielectrics. Concepts of electrostatic field and potential, electrostatic energy. Electric currents, magnetic fields and Ampere's law. Magnetic materials. Time-varying fields and Faraday's law of induction. Basic electric circuits. Electromagnetic waves and Maxwell's equations. Subject taught using the TEAL (Technology Enabled Active Learning) studio format which utilizes small group interaction and current technology to help students develop intuition about, and conceptual models of, physical phenomena.
R. Redwine, K. Perez
Textbooks (Fall 2016)

8.021 Physics II
______

Undergrad (Fall) Physics II
Prereq: Physics I (GIR), Calculus I (GIR), permission of instructor
Units: 5-0-7
Credit cannot also be received for8.02,8.022,CC.802,CC.8022,ES.802,ES.8022
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR1-2.30 (35-310) Lab: F1 (35-310) Recitation: W1 (35-310) +final
______
Introduction to electromagnetism and electrostatics: electric charge, Coulomb's law, electric structure of matter; conductors and dielectrics. Concepts of electrostatic field and potential, electrostatic energy. Electric currents, magnetic fields and Ampere's law. Magnetic materials. Time-varying fields and Faraday's law of induction. Basic electric circuits. Electromagnetic waves and Maxwell's equations. Designed for students with previous experience in 8.02; the subject is designated as 8.02 on the transcript. Enrollment limited.
E. Katsavounidis
Textbooks (Fall 2016)

8.022 Physics II
______

Undergrad (Fall, Spring) Physics II
Prereq: Physics I (GIR),Coreq: Calculus II (GIR)
Units: 5-0-7
Credit cannot also be received for8.02,8.021,CC.802,CC.8022,ES.802,ES.8022
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR2-3.30 (6-120) Recitation: WF10 (26-302) or WF11 (26-302) or WF12 (26-302) or WF1 (26-302) +final
______
Parallel to 8.02, but more advanced mathematically. Some knowledge of vector calculus assumed. Maxwell's equations, in both differential and integral form. Electrostatic and magnetic vector potential. Properties of dielectrics and magnetic materials. In addition to the theoretical subject matter, several experiments in electricity and magnetism are performed by the students in the laboratory.
J. Checkelsky
Textbooks (Fall 2016)

8.03 Physics III
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR), Physics II (GIR)
Units: 5-0-7
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR11.30-1 (6-120) Recitation: MW10 (26-314) or MW11 (26-314) or MW1 (26-328) or MW2 (26-328) +final
______
Mechanical vibrations and waves; simple harmonic motion, superposition, forced vibrations and resonance, coupled oscillations, and normal modes; vibrations of continuous systems; reflection and refraction; phase and group velocity. Optics; wave solutions to Maxwell's equations; polarization; Snell's Law, interference, Huygens's principle, Fraunhofer diffraction, and gratings.
Y-J. Lee
Textbooks (Fall 2016)

8.033 Relativity
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Physics II (GIR), Calculus II (GIR)
Units: 5-0-7
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW2.30-4 (6-120) Recitation: TR10 (26-328) or TR11 (26-328) or TR1 (26-328) or TR2 (26-328) +final
______
Einstein's postulates; consequences for simultaneity, time dilation, length contraction, and clock synchronization; Lorentz transformation; relativistic effects and paradoxes; Minkowski diagrams; invariants and four-vectors; momentum, energy, and mass; particle collisions. Relativity and electricity; Coulomb's law; magnetic fields. Brief introduction to Newtonian cosmology. Introduction to some concepts of general relativity; principle of equivalence. The Schwarzchild metric; gravitational red shift; particle and light trajectories; geodesics; Shapiro delay.
T. Slatyer
Textbooks (Fall 2016)

8.04 Quantum Physics I
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: 8.03; 18.03 or 18.034
Units: 5-0-7
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR9.30-11 (4-237) Recitation: MW9 (26-328) or MW10 (26-328) +final
______
Experimental basis of quantum physics: photoelectric effect, Compton scattering, photons, Franck-Hertz experiment, the Bohr atom, electron diffraction, deBroglie waves, and wave-particle duality of matter and light. Introduction to wave mechanics: Schroedinger's equation, wave functions, wave packets, probability amplitudes, stationary states, the Heisenberg uncertainty principle, and zero-point energies. Solutions to Schroedinger's equation in one dimension: transmission and reflection at a barrier, barrier penetration, potential wells, the simple harmonic oscillator. Schroedinger's equation in three dimensions: central potentials and introduction to hydrogenic systems.
V. Vuletic
Textbooks (Fall 2016)

8.044 Statistical Physics I
______

Undergrad (Spring)
Prereq: 8.03, 18.03
Units: 5-0-7
URL: http://web.mit.edu/physics/subjects/index.html
______
Introduction to probability, statistical mechanics, and thermodynamics. Random variables, joint and conditional probability densities, and functions of a random variable. Concepts of macroscopic variables and thermodynamic equilibrium, fundamental assumption of statistical mechanics, microcanonical and canonical ensembles. First, second, and third laws of thermodynamics. Numerous examples illustrating a wide variety of physical phenomena such as magnetism, polyatomic gases, thermal radiation, electrons in solids, and noise in electronic devices. Concurrent enrollment in 8.04 is recommended.
Staff

8.05 Quantum Physics II
______

Undergrad (Fall)
Prereq: 8.04
Units: 5-0-7
Credit cannot also be received for8.S05
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW12.30-2 (6-120) Recitation: TR10 (26-322) or TR11 (26-322) or TR1 (26-314) or TR2 (26-314) +final
______
Together 8.05 and 8.06 cover quantum physics with applications drawn from modern physics. General formalism of quantum mechanics: states, operators, Dirac notation, representations, measurement theory. Harmonic oscillator: operator algebra, states. Quantum mechanics in three dimensions: central potentials and the radial equation, bound and scattering states, qualitative analysis of wavefunctions. Angular momentum: operators, commutator algebra, eigenvalues and eigenstates, spherical harmonics. Spin: Stern-Gerlach devices and measurements, nuclear magnetic resonance, spin and statistics. Addition of angular momentum: Clebsch-Gordan series and coefficients, spin systems, and allotropic forms of hydrogen.
A. Adams
Textbooks (Fall 2016)

8.06 Quantum Physics III
______

Undergrad (Spring)
Prereq: 8.05
Units: 5-0-7
URL: http://web.mit.edu/physics/subjects/index.html
______
Continuation of 8.05. Units: natural units, scales of microscopic phenomena, applications. Time-independent approximation methods: degenerate and nondegenerate perturbation theory, variational method, Born-Oppenheimer approximation, applications to atomic and molecular systems. The structure of one- and two-electron atoms: overview, spin-orbit and relativistic corrections, fine structure, variational approximation, screening, Zeeman and Stark effects. Charged particles in a magnetic field: Landau levels and integer quantum hall effect. Scattering: general principles, partial waves, review of one-dimension, low-energy approximations, resonance, Born approximation. Time-dependent perturbation theory. Students research and write a paper on a topic related to the content of 8.05 and 8.06.
Staff

8.07 Electromagnetism II
______

Undergrad (Fall)
Prereq: 8.03, 18.03
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW11-12.30 (6-120) +final
______
Survey of basic electromagnetic phenomena: electrostatics, magnetostatics; electromagnetic properties of matter. Time-dependent electromagnetic fields and Maxwell's equations. Electromagnetic waves, emission, absorption, and scattering of radiation. Relativistic electrodynamics and mechanics.
S. Hughes
Textbooks (Fall 2016)

8.08 Statistical Physics II
______

Undergrad (Spring)
Prereq: 8.044, 8.05
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
Probability distributions for classical and quantum systems. Microcanonical, canonical, and grand canonical partition-functions and associated thermodynamic potentials. Conditions of thermodynamic equilibrium for homogenous and heterogenous systems. Applications: non-interacting Bose and Fermi gases; mean field theories for real gases, binary mixtures, magnetic systems, polymer solutions; phase and reaction equilibria, critical phenomena. Fluctuations, correlation functions and susceptibilities, and Kubo formulae. Evolution of distribution functions: Boltzmann and Smoluchowski equations.
Staff

8.09 Classical Mechanics III
______

Undergrad (Fall)
(Subject meets with8.309)
Prereq: 8.223
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR9.30-11 (56-114) Recitation: F1 (26-328) or F2 (26-328) +final
______
Covers Lagrangian and Hamiltonian mechanics, systems with constraints, rigid body dynamics, vibrations, central forces, Hamilton-Jacobi theory, action-angle variables, perturbation theory, and continuous systems. Provides an introduction to ideal and viscous fluid mechanics, including turbulence, as well as an introduction to nonlinear dynamics, including chaos. Students taking graduate version complete different assignments.
I. Stewart
Textbooks (Fall 2016)

Undergraduate Laboratory and Special Project Subjects

8.13 Experimental Physics I
______

Undergrad (Fall, Spring) Institute Lab
Prereq: 8.04
Units: 0-6-12
URL: http://web.mit.edu/physics/subjects/index.html
Lab: MW9-12 (4-361) or MW2-5 (4-361) or TR9-12 (4-361) or TR2-5 (4-361)
______
G. Roland, J. Conrad, A. Levine, P. Zuccon
Textbooks (Fall 2016)

8.14 Experimental Physics II
______

Undergrad (Spring)
Prereq: 8.05, 8.13
Units: 0-6-12
URL: http://web.mit.edu/physics/subjects/index.html
______
Four fundamental laboratory experiments are carried out each term, covering most aspects of modern physics relating to names such as Rutherford, Franck-Hertz, Hall, Ramsauer, Doppler, Fraunhofer, Faraday, Mossbauer, Compton, and Stern-Gerlach. Stresses basic experimental techniques and data analysis, and written and oral presentation of experiment results. 8.14 requires knowledge of quantum mechanics at the 8.05 level.
G. Roland

8.18 Research Problems in Undergraduate Physics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Opportunity for undergraduates to engage in experimental or theoretical research under the supervision of a staff member. Specific approval required in each case.
Consult N. Mavalvala
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

8.19 Readings in Physics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Supervised reading and library work. Choice of material and allotment of time according to individual needs. For students who want to do work not provided for in the regular subjects. Specific approval required in each case.
Consult N. Mavalvala
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

Undergraduate Elective Subjects

8.20 Introduction to Special Relativity
______

Undergrad (IAP) Rest Elec in Sci & Tech
Prereq: Physics I (GIR), Calculus I (GIR)
Units: 2-0-7
URL: http://web.mit.edu/physics/subjects/index.html
______
Introduces the basic ideas and equations of Einstein's special theory of relativity. Topics include Lorentz transformations, length contraction and time dilation, four vectors, Lorentz invariants, relativistic energy and momentum, relativistic kinematics, Doppler shift, space-time diagrams, relativity paradoxes, and some concepts of general relativity. Intended for freshmen and sophomores. Not usable as a restricted elective by Physics majors. Credit cannot be received for 8.20 if credit for 8.033 is or has been received in the same or prior terms.
J. Formaggio

8.21 Physics of Energy
______

Not offered academic year 2016-2017Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Physics II (GIR), Calculus II (GIR), Chemistry (GIR)
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
Subject Cancelled Subject Cancelled
______
A comprehensive introduction to the fundamental physics of energy systems that emphasizes quantitative analysis. Focuses on the fundamental physical principles underlying energy processes and on the application of these principles to practical calculations. Applies mechanics and electromagnetism to energy systems; introduces and applies basic ideas from thermodynamics, quantum mechanics, and nuclear physics. Examines energy sources, conversion, transport, losses, storage, conservation, and end uses. Analyzes the physics of side effects, such as global warming and radiation hazards. Provides students with technical tools and perspective to evaluate energy choices quantitatively at both national policy and personal levels.
Staff

8.223 Classical Mechanics II
______

Undergrad (IAP)
Prereq: Physics I (GIR), Calculus II (GIR)
Units: 2-0-4
______
A broad, theoretical treatment of classical mechanics, useful in its own right for treating complex dynamical problems, but essential to understanding the foundations of quantum mechanics and statistical physics. Generalized coordinates, Lagrangian and Hamiltonian formulations, canonical transformations, and Poisson brackets. Applications to continuous media. The relativistic Lagrangian and Maxwell's equations.
Staff

8.224 Exploring Black Holes: General Relativity and Astrophysics
______

Not offered academic year 2017-2018Undergrad (Spring)
Prereq: 8.033 or 8.20
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Study of physical effects in the vicinity of a black hole as a basis for understanding general relativity, astrophysics, and elements of cosmology. Extension to current developments in theory and observation. Energy and momentum in flat space-time; the metric; curvature of space-time near rotating and nonrotating centers of attraction; trajectories and orbits of particles and light; elementary models of the Cosmos. Weekly meetings include an evening seminar and recitation. The last third of the term is reserved for collaborative research projects on topics such as the Global Positioning System, solar system tests of relativity, descending into a black hole, gravitational lensing, gravitational waves, Gravity Probe B, and more advanced models of the cosmos. Subject has online components that are open to selected MIT alumni. Alumni wishing to participate should contact Professor Bertschinger at edbert@mit.edu. Limited to 40.
E. Bertschinger

8.225[J] Einstein, Oppenheimer, Feynman: Physics in the 20th Century
______

Not offered academic year 2017-2018Undergrad (Spring) HASS Humanities
(Same subject asSTS.042[J])
Prereq: None
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Explores the changing roles of physics and physicists during the 20th century. Topics range from relativity theory and quantum mechanics to high-energy physics and cosmology. Examines the development of modern physics within shifting institutional, cultural, and political contexts, such as physics in Imperial Britain, Nazi Germany, US efforts during World War II, and physicists' roles during the Cold War. Enrollment limited.
D. I. Kaiser

8.226 Forty-three Orders of Magnitude
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 8.04, 8.044; or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Examines the widespread societal implications of current scientific discoveries in physics across forty-three orders of magnitude in length scale. Addresses topics ranging from climate change to nuclear nonproliferation. Students develop their ability to express concepts at a level accessible to the public and to present a well-reasoned argument on a topic that is a part of the national debate. Requires diverse writing assignments, including substantial papers. Enrollment limited.
J. Conrad

8.231 Physics of Solids I
______

Undergrad (Fall)
Prereq: 8.044,Coreq: 8.05
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR1-2.30 (4-261) Recitation: F1 (26-210)
______
Introduction to the basic concepts of the quantum theory of solids. Topics: periodic structure and symmetry of crystals; diffraction; reciprocal lattice; chemical bonding; lattice dynamics, phonons, thermal properties; free electron gas; model of metals; Bloch theorem and band structure, nearly free electron approximation; tight binding method; Fermi surface; semiconductors, electrons, holes, impurities; optical properties, excitons; and magnetism.
X-G. Wen
Textbooks (Fall 2016)

8.241 Introduction to Biological Physics
______

Undergrad (Spring)
Prereq: Physics II (GIR); 8.044 or 5.60
Units: 4-0-8
______
Introduces the main concepts of biological physics, with a focus on biophysical phenomena at the molecular and cellular scales. Presents the role of entropy and diffusive transport in living matter; challenges to life resulting from the highly viscous environment present at microscopic scales, including constraints on force, motion and transport within cells, tissues, and fluids; principles of how cellular machinery (e.g., molecular motors) can convert electro-chemical energy sources to mechanical forces and motion. Also covers polymer physics relevant to DNA and other biological polymers, including the study of configurations, fluctuations, rigidity, and entropic elasticity.
J. Gore, I. Cisse

8.251 String Theory for Undergraduates
______

Not offered academic year 2017-2018Undergrad (Spring)
Prereq: 8.033, 8.044, 8.05
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
Introduction to the main concepts of string theory, i.e. quantum mechanics of a relativistic string. Develops aspects of string theory and makes it accessible to students familiar with basic electromagnetism and statistical mechanics, including the study of D-branes and string thermodynamics.
H. Liu

8.276 Nuclear and Particle Physics
______

Not offered academic year 2017-2018Undergrad (Spring)
Prereq: 8.033, 8.04
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
Presents a modern view of the fundamental structure of matter. Starting from the Standard Model, which views leptons and quarks as basic building blocks of matter, establishes the properties and interactions of these particles. Explores applications of this phenomenology to both particle and nuclear physics. Emphasizes current topics in nuclear and particle physics research at MIT. Intended for students with a basic knowledge of relativity and quantum physics concepts.
M. Williams

8.277 Introduction to Particle Accelerators
______

Not offered academic year 2017-2018Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: 6.013 or 8.07; permission of instructor
Units arranged
Lecture: MW9.30-11 (8-205)
______
Principles of acceleration: beam properties; linear accelerators, synchrotrons, and storage rings. Accelerator technologies: radio frequency cavities, bending and focusing magnets, beam diagnostics. Particle beam optics and dynamics. Special topics: measures of accelerators performance in science, medicine and industry; synchrotron radiation sources; free electron lasers; high-energy colliders; and accelerators for radiation therapy. May be repeated for credit for a maximum of 12 units.
W. Barletta
No required or recommended textbooks

8.282[J] Introduction to Astronomy
______

Undergrad (Spring) Rest Elec in Sci & Tech
(Same subject as12.402[J])
Prereq: Physics I (GIR)
Units: 3-0-6
URL: http://web.mit.edu/physics/subjects/index.html
______
Quantitative introduction to physics of the solar system, stars, interstellar medium, the galaxy, and universe, as determined from a variety of astronomical observations and models. Topics: planets, planet formation; stars, the Sun, "normal" stars, star formation; stellar evolution, supernovae, compact objects (white dwarfs, neutron stars, and black holes), plusars, binary x-ray sources; star clusters, globular and open clusters; interstellar medium, gas, dust, magnetic fields, cosmic rays; distance ladder; galaxies, normal and active galaxies, jets; gravitational lensing; large scaling structure; Newtonian cosmology, dynamical expansion and thermal history of the universe; cosmic microwave background radiation; big bang nucleosynthesis. No prior knowledge of astronomy necessary. Not usable as a restricted elective by Physics majors.
Staff

8.284 Modern Astrophysics
______

Undergrad (Spring)
Prereq: 8.04,Coreq: 8.05
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Applications of physics (Newtonian, statistical, and quantum mechanics) to fundamental processes that occur in celestial objects. Includes main-sequence stars, collapsed stars (white dwarfs, neutron stars, and black holes), pulsars, supernovae, the interstellar medium, galaxies, and as time permits, active galaxies, quasars, and cosmology. Observational data discussed. No prior knowledge of astronomy is required.
Staff

8.286 The Early Universe
______

Not offered academic year 2017-2018Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: 18.03, Physics II (GIR)
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW11-12.30 (4-163)
______
Introduction to modern cosmology. First half deals with the development of the big bang theory from 1915 to 1980, and latter half with recent impact of particle theory. Topics: special relativity and the Doppler effect, Newtonian cosmological models, introduction to non-Euclidean spaces, thermal radiation and early history of the universe, big bang nucleosynthesis, introduction to grand unified theories and other recent developments in particle theory, baryogenesis, the inflationary universe model, and the evolution of galactic structure.
A. Guth
Textbooks (Fall 2016)

8.287[J] Observational Techniques of Optical Astronomy
______

Undergrad (Fall) Institute Lab
(Same subject as12.410[J])
Prereq: 8.282J, 12.402J, 12.409, or other introductory astronomy course;Coreq: 8.03
Units: 3-4-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MWF1 (54-517) Lab: TBA
______
Fundamental physical and optical principles used for astronomical measurements at visible wavelengths and practical methods of astronomical observations. Topics: astronomical coordinates, time, optics, telescopes, photon counting, signal-to-noise ratios, data analysis (including least-squares model fitting), limitations imposed by the Earth's atmosphere on optical observations, CCD detectors, photometry, spectroscopy, astrometry, and time variability. Project at Wallace Astrophysical Observatory. Written and oral project reports. Limited to 18; preference to Course 8 and Course 12 majors and minors.
R. Binzel, A. Bosh
Textbooks (Fall 2016)

8.290[J] Extrasolar Planets: Physics and Detection Techniques
______

Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject as12.425[J])
(Subject meets with12.625)
Prereq: 8.03, 18.03
Units: 2-1-9
Lecture: TR1.30-3 (54-824)
______
Presents basic principles of planet atmospheres and interiors applied to the study of extrasolar planets. Focuses on fundamental physical processes related to observable extrasolar planet properties. Provides a quantitative overview of detection techniques. Introduction to the feasibility of the search for Earth-like planets, biosignatures and habitable conditions on extrasolar planets. Students taking graduate version complete additional assignments.
S. Seager
No required or recommended textbooks

8.292[J] Fluid Physics
______

Undergrad (Spring)
(Same subject as12.330[J])
Prereq: 8.044, 5.60, or permission of instructor
Units: 3-0-9
______
A physics-based introduction to the properties of fluids and fluid systems, with examples drawn from a broad range of sciences, including atmospheric physics and astrophysics. Definitions of fluids and the notion of continuum. Equations of state and continuity, hydrostatics and conservation of momentum; ideal fluids and Euler's equation; viscosity and the Navier-Stokes equation. Energy considerations, fluid thermodynamics, and isentropic flow. Compressible versus incompressible and rotational versus irrotational flow; Bernoulli's theorem; steady flow, streamlines and potential flow. Circulation and vorticity. Kelvin's theorem. Boundary layers. Fluid waves and instabilities. Quantum fluids.
D. Cziczo

8.295 Practical Work Experience
(New)
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units: 0-1-0 [P/D/F]
TBA.
______
For Course 8 students participating in off-campus work experiences in physics. Before registering for this subject, students must have an employment offer from a company or organization and must identify a Physics supervisor. Upon completion of the work, student must submit a letter from the employer describing the work accomplished, along with a substantive final report from the student approved by the MIT supervisor. Subject to departmental approval. Consult departmental academic office.
Consult N. Mavalvala
No required or recommended textbooks

8.297 Physics of the 21st Century
______

Undergrad (Spring)
Not offered regularly; consult department
Prereq: 8.033, 8.044, 8.05, 8.13
Units: 4-0-8
______
Students study four topics in depth from themes of current interest over the course of the term. Topic examples include Bose-Einstein condensates, dark energy, neutrino interactions, superconductivity, photonics, semiconductor nanostructures, exoplanets, and space plasmas.
P. Fisher

8.298 Selected Topics in Physics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Presentation of topics of current interest, with content varying from year to year.
Consult I. Stewart
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

8.299 Physics Teaching
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
For qualified undergraduate students interested in gaining some experience in teaching. Laboratory, tutorial, or classroom teaching under the supervision of a faculty member. Students selected by interview.
Consult N. Mavalvala
No required or recommended textbooks

8.S10 Special Subject: Physics
______

Undergrad (IAP) Can be repeated for credit
Prereq: None
Units arranged
______
Opportunity for group study of subjects in physics not otherwise included in the curriculum.
A. Adams, K. Ellenbogen

8.S30 Special Subject: Physics
______

Undergrad (IAP)
Prereq: None
Units arranged
______
Opportunity for group study of subjects in physics not otherwise included in the curriculum.
A. Bernstein, J. Walsh

8.S50 Special Subject: Physics
______

Undergrad (Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
______
Opportunity for group study of subjects in physics not otherwise included in the curriculum.
E. Bertschinger

8.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Research opportunities in physics. For further information, contact the departmental UROP coordinator.
N. Mavalvala
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

8.THU Undergraduate Physics Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Program of research leading to the writing of an S.B. thesis; to be arranged by the student under approved supervision.
Information: N. Mavalvala
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|8.01-8.299 plus UROP and THU|8.300-8.999 plus THG|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 8: Physics
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Course 8: Physics
Fall 2016


Graduate Subjects

8.309 Classical Mechanics III
(New)
______

Graduate (Fall)
(Subject meets with8.09)
Prereq: None
Units: 4-0-8
Lecture: TR9.30-11 (56-114) Recitation: F1 (26-328) or F2 (26-328) +final
______
Covers Lagrangian and Hamiltonian mechanics, systems with constraints, rigid body dynamics, vibrations, central forces, Hamilton-Jacobi theory, action-angle variables, perturbation theory, and continuous systems. Provides an introduction to ideal and viscous fluid mechanics, including turbulence, as well as an introduction to nonlinear dynamics, including chaos. Students taking graduate version complete different assignments.
I. Stewart
No required or recommended textbooks

8.311 Electromagnetic Theory I
______

Graduate (Spring)
Prereq: 8.07
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
Basic principles of electromagnetism: experimental basis, electrostatics, magnetic fields of steady currents, motional emf and electromagnetic induction, Maxwell's equations, propagation and radiation of electromagnetic waves, electric and magnetic properties of matter, and conservation laws. Subject uses appropriate mathematics but emphasizes physical phenomena and principles.
Staff

8.321 Quantum Theory I
______

Graduate (Fall)
Prereq: 8.05
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW10-11.30 (4-265) Recitation: T10 (4-265) or F10 (4-261) +final
______
Textbooks (Fall 2016)

8.322 Quantum Theory II
______

Graduate (Spring)
Prereq: 8.07, 8.321
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
A two-term subject on quantum theory, stressing principles: uncertainty relation, observables, eigenstates, eigenvalues, probabilities of the results of measurement, transformation theory, equations of motion, and constants of motion. Symmetry in quantum mechanics, representations of symmetry groups. Variational and perturbation approximations. Systems of identical particles and applications. Time-dependent perturbation theory. Scattering theory: phase shifts, Born approximation. The quantum theory of radiation. Second quantization and many-body theory. Relativistic quantum mechanics of one electron.
R. Jackiw

8.323 Relativistic Quantum Field Theory I
______

Graduate (Spring)
Prereq: 8.321
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
A one-term self-contained subject in quantum field theory. Concepts and basic techniques are developed through applications in elementary particle physics, and condensed matter physics. Topics: classical field theory, symmetries, and Noether's theorem. Quantization of scalar fields, spin fields, and Gauge bosons. Feynman graphs, analytic properties of amplitudes and unitarity of the S-matrix. Calculations in quantum electrodynamics (QED). Introduction to renormalization.
Staff

8.324 Relativistic Quantum Field Theory II
______

Graduate (Fall)
Prereq: 8.322, 8.323
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW EVE (4.30-6 PM) (32-144) Recitation: F10 (26-414)
______
The second term of the quantum field theory sequence. Develops in depth some of the topics discussed in 8.323 and introduces some advanced material. Topics: perturbation theory and Feynman diagrams, scattering theory, Quantum Electrodynamics, one loop renormalization, quantization of non-abelian gauge theories, the Standard Model of particle physics, other topics.
H. Liu
Textbooks (Fall 2016)

8.325 Relativistic Quantum Field Theory III
______

Graduate (Spring)
Prereq: 8.324
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
The third and last term of the quantum field theory sequence. Its aim is the proper theoretical discussion of the physics of the standard model. Topics: quantum chromodynamics; Higgs phenomenon and a description of the standard model; deep-inelastic scattering and structure functions; basics of lattice gauge theory; operator products and effective theories; detailed structure of the standard model; spontaneously broken gauge theory and its quantization; instantons and theta-vacua; topological defects; introduction to supersymmetry.
Staff

8.333 Statistical Mechanics I
______

Graduate (Fall)
Prereq: 8.044, 8.05
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW2.30-4 (4-163) Recitation: F2.30-4 (4-163) +final
______
Textbooks (Fall 2016)

8.334 Statistical Mechanics II
______

Graduate (Spring)
Prereq: 8.333
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
A two-term subject on statistical mechanics. Basic principles are examined in 8.333: the laws of thermodynamics and the concepts of temperature, work, heat, and entropy. Postulates of classical statistical mechanics, microcanonical, canonical, and grand canonical distributions; applications to lattice vibrations, ideal gas, photon gas. Quantum statistical mechanics; Fermi and Bose systems. Interacting systems: cluster expansions, van der Waal's gas, and mean-field theory. Topics from modern statistical mechanics are explored in 8.334: the hydrodynamic limit and classical field theories. Phase transitions and broken symmetries: universality, correlation functions, and scaling theory. The renormalization approach to collective phenomena. Dynamic critical behavior. Random systems.
8.333: M. Kardar; 8.334: Staff

8.351[J] Classical Mechanics: A Computational Approach
______

Graduate (Fall)
(Same subject as6.946[J],12.620[J])
Prereq: Physics I (GIR), 18.03, permission of instructor
Units: 3-3-6
Credit cannot also be received for12.008
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MWF11 (54-819) Lab: W EVE (7-10 PM) (14-0637)
______
Classical mechanics in a computational framework, Lagrangian formulation, action, variational principles, and Hamilton's principle. Conserved quantities, Hamiltonian formulation, surfaces of section, chaos, and Liouville's theorem. Poincaré integral invariants, Poincaré-Birkhoff and KAM theorems. Invariant curves and cantori. Nonlinear resonances, resonance overlap and transition to chaos. Symplectic integration. Adiabatic invariants. Applications to simple physical systems and solar system dynamics. Extensive use of computation to capture methods, for simulation, and for symbolic analysis. Programming experience required. Students taking the graduate version complete additional assignments.
J. Wisdom, G. J. Sussman
Textbooks (Fall 2016)

8.361 Quantum Theory of Many-Particle Systems
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 8.322, 8.333
Units: 3-0-9
______
Introduces general many-body theory applicable to low temperature, nuclear, and solid-state physics. Reviews occupation number representation and classical Mayer expansion. Perturbation theory: diagrammatic expansions and linked-cluster theorem for zero or finite temperature systems of fermions or bosons. Green's functions: analytic properties, equations of motion, relation to observables, approximations, linear response theory, and random phase approximation. Superconductivity: electron-phonon interaction, instability of normal state, BCS ground state, perturbation theory.
Staff

8.370[J] Quantum Computation
______

Graduate (Fall)
(Same subject as2.111[J],18.435[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (4-370) +final
______
Provides an introduction to the theory and practice of quantum computation. Topics covered: physics of information processing; quantum algorithms including the factoring algorithm and Grover's search algorithm; quantum error correction; quantum communication and cryptography. Knowledge of quantum mechanics helpful but not required.
I. Chuang, E. Farhi, S. Lloyd, P. Shor
Textbooks (Fall 2016)

8.371[J] Quantum Information Science
______

Graduate (Spring)
(Same subject as6.443[J],18.436[J])
Prereq: 18.435
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Examines quantum computation and quantum information. Topics include quantum circuits, the quantum Fourier transform and search algorithms, the quantum operations formalism, quantum error correction, Calderbank-Shor-Steane and stabilizer codes, fault tolerant quantum computation, quantum data compression, quantum entanglement, capacity of quantum channels, and quantum cryptography and the proof of its security. Prior knowledge of quantum mechanics required.
I. Chuang

8.381, 8.382 Selected Topics in Theoretical Physics
______

Graduate (Fall, Spring)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Topics of current interest in theoretical physics, varying from year to year. Subject not routinely offered; given when sufficient interest is indicated.
Staff

8.391 Pre-Thesis Research
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

8.392 Pre-Thesis Research
______

Graduate (Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Advanced problems in any area of experimental or theoretical physics, with assigned reading and consultations.
Staff
No textbook information available

8.395[J] Teaching College-Level Science and Engineering
______

Graduate (Fall)
(Same subject as1.95[J],5.95[J],7.59[J],18.094[J])
(Subject meets with2.978)
Prereq: None
Units: 2-0-2 [P/D/F]
URL: https://wikis.mit.edu/confluence/pages/viewpage.action?pageId=110876412
Lecture: R9-11 (4-149)
______
Participatory seminar focuses on the knowledge and skills necessary for teaching science and engineering in higher education. Topics include theories of adult learning; course development; promoting active learning, problemsolving, and critical thinking in students; communicating with a diverse student body; using educational technology to further learning; lecturing; creating effective tests and assignments; and assessment and evaluation. Students research and present a relevant topic of particular interest. Appropriate for both novices and those with teaching experience.
J. Rankin
No required or recommended textbooks

8.398 Selected Topics in Graduate Physics
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: R9-11 (4-265)
______
Presentation of topics of current interest with content varying from year to year.
Consult N. Mavalvala
No required or recommended textbooks

8.399 Physics Teaching
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
For qualified graduate students interested in gaining some experience in teaching. Laboratory, tutorial, or classroom teaching under the supervision of a faculty member. Students selected by interview.
Consult C. Paus
No required or recommended textbooks

Physics of Atoms, Radiation, Solids, Fluids, and Plasmas

8.421 Atomic and Optical Physics I
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 8.05
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
The first of a two-term subject sequence that provides the foundations for contemporary research in selected areas of atomic and optical phsyics. The interaction of radiation with atoms: resonance; absorption, stimulated and spontaneous emission; methods of resonance, dressed atom formalism, masers and lasers, cavity quantum electrodynamics; structure of simple atoms, behavior in very strong fields; fundamental tests: time reversal, parity violations, Bell's inequalities; and experimental methods.
Staff

8.422 Atomic and Optical Physics II
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 8.05
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
The second of a two-term subject sequence that provides the foundations for contemporary research in selected areas of atomic and optical physics. Non-classical states of light- squeezed states; multi-photon processes, Raman scattering; coherence- level crossings, quantum beats, double resonance, superradiance; trapping and cooling- light forces, laser cooling, atom optics, spectroscopy of trapped atoms and ions; atomic interactions- classical collisions, quantum scattering theory, ultracold collisions; and experimental methods.
Staff

8.431[J] Nonlinear Optics
______

Graduate (Spring)
(Same subject as6.634[J])
Prereq: 6.013 or 8.07
Units: 3-0-9
______
Techniques of nonlinear optics with emphasis on fundamentals for research and engineering in optics, photonics, and spectroscopy. Electro optic modulators, harmonic generation, and frequency conversion devices. Nonlinear effects in optical fibers including self-phase modulation, nonlinear wave propagation, and solitons. Interaction of light with matter, laser operation, density matrix techniques, nonlinear spectroscopies, and femtosecond optics.
J. G. Fujimoto

8.481, 8.482 Selected Topics in Physics of Atoms and Radiation
______

Graduate (Fall, Spring)
Not offered regularly; consult department
Prereq: 8.321
Units: 3-0-9
______
Presentation of topics of current interest, with content varying from year to year. Subject not routinely offered; given when sufficient interest is indicated.
Staff

8.511 Theory of Solids I
______

Graduate (Fall)
Prereq: 8.231
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW1-2.30 (4-153)
______
First term of a theoretical treatment of the physics of solids. Concept of elementary excitations. Symmetry- translational, rotational, and time-reversal invariances- theory of representations. Energy bands- APW, OPW, pseudopotential and LCAO schemes. Survey of electronic structure of metals, semimetals, semiconductors, and insulators, excitons, critical points, response functions, and interactions in the electron gas.
L. Levitov
Textbooks (Fall 2016)

8.512 Theory of Solids II
______

Graduate (Spring)
Prereq: 8.511
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Second term of a theoretical treatment of the physics of solids. Interacting electron gas: many-body formulation, Feynman diagrams, random phase approximation and beyond. General theory of linear response: dielectric function; sum rules; plasmons; optical properties; applications to semiconductors, metals, and insulators. Transport properties: non-interacting electron gas with impurities, diffusons. Quantum Hall effect: integral and fractional. Electron-phonon interaction: general theory, applications to metals, semiconductors and insulators, polarons, and field-theory description. Superconductivity: experimental observations, phenomenological theories, and BCS theory.
Staff

8.513 Many-Body Theory for Condensed Matter Systems
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 8.05, 8.08, 8.033, 8.231J
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Concepts and physical pictures behind various phenomena that appear in interacting many-body systems. Visualization occurs through concentration on path integral, mean-field theories and semiclassical picture of fluctuations around mean-field state. Topics covered: interacting boson/fermion systems, Fermi liquid theory and bosonization, symmetry breaking and nonlinear sigma-model, quantum gauge theory, quantum Hall theory, mean-field theory of spin liquids and quantum order, string-net condensation and emergence of light and fermions.
L. Levitov

8.514 Strongly Correlated Systems in Condensed Matter Physics
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 8.322, 8.333
Units: 3-0-9
______
Study of condensed matter systems where interactions between electrons play an important role. Topics vary depending on lecturer but may include low-dimension magnetic and electronic systems, disorder and quantum transport, magnetic impurities (the Kondo problem), quantum spin systems, the Hubbard model and high-temperature superconductors. Topics are chosen to illustrate the application of diagrammatic techniques, field-theory approaches, and renormalization group methods in condensed matter physics.
X. Wen

8.581, 8.582 Selected Topics in Condensed Matter Physics
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Presentation of topics of current interest, with contents varying from year to year. Subject not routinely offered; given when sufficient interest is indicated.
Staff

8.590[J] Topics in Biophysics and Physical Biology
______

Graduate (Fall)
(Same subject as7.74[J],20.416[J])
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: F1-2.30 (56-167)
______
Provides broad exposure to research in biophysics and physical biology, with emphasis on the critical evaluation of scientific literature. Weekly meetings include in-depth discussion of scientific literature led by distinct faculty on active research topics. Each session also includes brief discussion of non-research topics including effective presentation skills, writing papers and fellowship proposals, choosing scientific and technical research topics, time management, and scientific ethics.
I. Cisse, N. Fakhri, M. Guo
No required or recommended textbooks

8.591[J] Systems Biology
______

Graduate (Fall)
(Same subject as7.81[J])
(Subject meets with7.32)
Prereq: 18.03, 18.05; or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR1-2.30 (4-159) Recitation: TBA +final
______
Introduction to cellular and population-level systems biology with an emphasis on synthetic biology, modeling of genetic networks, cell-cell interactions, and evolutionary dynamics. Cellular systems include genetic switches and oscillators, network motifs, genetic network evolution, and cellular decision-making. Population-level systems include models of pattern formation, cell-cell communication, and evolutionary systems biology. Students taking graduate version explore the subject in more depth.
J. Gore
Textbooks (Fall 2016)

8.592[J] Statistical Physics in Biology
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject asHST.452[J])
Prereq: 8.333 or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
A survey of problems at the interface of statistical physics and modern biology: bioinformatic methods for extracting information content of DNA; gene finding, sequence comparison, phylogenetic trees. Physical interactions responsible for structure of biopolymers; DNA double helix, secondary structure of RNA, elements of protein folding. Considerations of force, motion, and packaging; protein motors, membranes. Collective behavior of biological elements; cellular networks, neural networks, and evolution.
M. Kardar, L. Mirny

8.593[J] Biological Physics
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject asHST.450[J])
Prereq: 8.044 recommended but not necessary
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
Designed to provide seniors and first-year graduate students with a quantitative, analytical understanding of selected biological phenomena. Topics include experimental and theoretical basis for the phase boundaries and equation of state of concentrated protein solutions, with application to diseases such as sickle cell anemia and cataract. Protein-ligand binding and linkage and the theory of allosteric regulation of protein function, with application to proteins as stores as transporters in respiration, enzymes in metabolic pathways, membrane receptors, regulators of gene expression, and self-assembling scaffolds. The physics of locomotion and chemoreception in bacteria and the biophysics of vision, including the theory of transparency of the eye, molecular basis of photo reception, and the detection of light as a signal-to-noise discrimination.
G. Benedek

8.613[J] Introduction to Plasma Physics I
______

Graduate (Fall)
(Same subject as22.611[J])
Prereq: 6.013 or 8.07; 18.04 orCoreq: 18.075
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR11-12.30 (NW16-213)
______
Introduces plasma phenomena relevant to energy generation by controlled thermonuclear fusion and to astrophysics. Elementary plasma concepts, plasma characterization. Motion of charged particles in magnetic fields. Coulomb collisions, relaxation times, transport processes. Two-fluid hydrodynamic and MHD descriptions. Plasma confinement by magnetic fields, simple equilibrium and stability analysis. Wave propagation in a magnetic field; application to RF plasma heating. Introduction to kinetic theory; Vlasov, Boltzmann and Fokker-Planck equations; relation of fluid and kinetic descriptions. Electron and ion acoustic plasma waves, Landau damping.
A. White
Textbooks (Fall 2016)

8.614[J] Introduction to Plasma Physics II
______

Graduate (Spring)
(Same subject as22.612[J])
Prereq: 6.651J, 8.613J, or 22.611J
Units: 3-0-9
______
Linear waves and instabilities in magnetized plasma; solutions of Vlasov-Maxwell equations in homogeneous and inhomogeneous plasmas; conservation principles for energy and momentum; quasi-linear theory and nonlinear stabilization; solitons and coherent nonlinear phenomena; collisions and discrete particle effects; fluctuations in a stable plasma; Fokker-Planck equation and transport phenomena. A subject description tailored to fit the background and interests of the attending students distributed shortly before and at the beginning of the subject.
Staff

8.624 Plasma Waves
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 8.613J
Units: 3-0-9
______
Comprehensive theory of electromagnetic waves in a magnetized plasma. Wave propagation in cold and hot plasmas. Energy flow. Absorption by Landau and cyclotron damping and by transit time magnetic pumping (TTMP). Wave propagation in inhomogeneous plasma: accessibility, WKB theory, mode conversion, connection formulae, and Budden tunneling. Applications to RF plasma heating, wave propagation in the ionosphere and laser-plasma interactions. Wave propagation in toroidal plasmas, and applications to ion cyclotron (ICRF), electron cyclotron (ECRH), and lower hybrid (LHH) wave heating. Quasi-linear theory and applications to RF current drive in tokamaks. Extensive discussion of relevant experimental observations.
M. Porkolab

8.641 Physics of High-Energy Plasmas I
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 8.613J
Units: 3-0-9
______

8.642 Physics of High-Energy Plasmas II
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 8.613
Units: 3-0-9
______
Basic concepts of plasmas, with temperatures of thermonuclear interest, relevant to fusion research and astrophysics. Microscopic transport processes due to interparticle collisions and collective modes (e.g., microinstabilities). Relevant macroscopic transport coefficients (electrical resistivity, thermal conductivities, particle "diffusion"). Runaway and slide-away regimes. Magnetic reconnection processes and their relevance to experimental observations. Radiation emission from inhomogeneous plasmas. Conditions for thermonuclear burning and ignition (D-T and "advanced" fusion reactions, plasmas with polarized nuclei). Role of "impurity" nuclei. "Finite-β" (pressure) regimes and ballooning modes. Convective modes in configuration and velocity space. Trapped particle regimes. Nonlinear and explosive instabilities. Interaction of positive and negative energy modes. Each subject can be taken independently.
Staff

8.681, 8.682 Selected Topics in Fluid and Plasma Physics
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: 8.613J
Units: 3-0-9
______
Presentation of topics of current interest, with content varying from year to year. Subject not routinely offered; given when interest is indicated.
Consult M. Porkolab

Nuclear and Particle Physics

8.701 Introduction to Nuclear and Particle Physics
______

Graduate (Fall)
Prereq: None.Coreq: 8.321
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR1.30-3 (26-414)
______
The phenomenology and experimental foundations of particle and nuclear physics; the fundamental forces and particles, composites. Interactions of particles with matter, and detectors. SU(2), SU(3), models of mesons and baryons. QED, weak interactions, parity violation, lepton-nucleon scattering, and structure functions. QCD, gluon field and color. W and Z fields, electro-weak unification, the CKM matrix. Nucleon-nucleon interactions, properties of nuclei, single- and collective- particle models. Electron and hadron interactions with nuclei. Relativistic heavy ion collisions, and transition to quark-gluon plasma.
J. Formaggio
Textbooks (Fall 2016)

8.711 Nuclear Physics
______

Graduate (Spring)
Prereq: 8.321, 8.701
Units: 4-0-8
______
Modern, advanced study in the experimental foundations and theoretical understanding of the structure of nuclei, beginning with the two- and three-nucleon problems. Basic nuclear properties, collective and single-particle motion, giant resonances, mean field models, interacting boson model. Nuclei far from stability, nuclear astrophysics, big-bang and stellar nucleosynthesis. Electron scattering: nucleon momentum distributions, scaling, olarization observables. Parity-violating electron scattering. Neutrino physics. Current results in relativistic heavy ion physics and hadronic physics. Frontiers and future facilities.
J. Matthews

8.712 Advanced Topics in Nuclear Physics
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: 8.711 or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Subject for experimentalists and theorists with rotation of the following topics: (1) Nuclear chromodynamics-- introduction to QCD, structure of nucleons, lattice QCD, phases of hadronic matter; and relativistic heavy ion collisions. (2) Medium-energy physics-- nuclear and nucleon structure and dynamics studied with medium- and high-energy probes (neutrinos, photons, electrons, nucleons, pions, and kaons). Studies of weak and strong interactions.
Staff

8.781, 8.782 Selected Topics in Nuclear Theory
______

Graduate (Fall, Spring)
Not offered regularly; consult department
Prereq: 8.323
Units: 3-0-9
______
Presents topics of current interest in nuclear structure and reaction theory, with content varying from year to year. Subject not routinely offered; given when sufficient interest is indicated.
Consult E. Farhi

8.811 Particle Physics
______

Graduate (Fall)
Prereq: 8.701
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW1.30-3 Recitation: F1.30
______
Modern review of particles, interactions, and recent experiments. Experimental and analytical methods. QED, electroweak theory, and the Standard Model as tested in recent key experiments at ee and pp colliders. Mass generation, W, Z, and Higgs physics. Weak decays of mesons, including heavy flavors with QCD corrections. Mixing phenomena for K, D, B mesons and neutrinos. CP violation with results from B-factories. Future physics expectations: Higgs, SUSY, sub-structure as addressed by new experiments at the LHC collider.
L. Winslow
Textbooks (Fall 2016)

8.812 Graduate Experimental Physics
______

Not offered academic year 2016-2017Graduate (IAP)
Prereq: 8.701
Units: 1-8-3
______
Provides practical experience in particle detection with verification by (Feynman) calculations. Students perform three experiments; at least one requires actual construction following design. Topics include Compton effect, Fermi constant in muon decay, particle identification by time-of-flight, Cerenkov light, calorimeter response, tunnel effect in radioactive decays, angular distribution of cosmic rays, scattering, gamma-gamma nuclear correlations, and modern particle localization.
U. Becker

8.821 String Theory
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 8.324
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
An introduction to string theory. Basics of conformal field theory; light-cone and covariant quantization of the relativistic bosonic string; quantization and spectrum of supersymmetric 10-dimensional string theories; T-duality and D-branes; toroidal compactification and orbifolds; 11-dimensional supergravity and M-theory.
H. Liu

8.831[J] Supersymmetric Quantum Field Theories
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
(Same subject as18.396[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Topics selected from the following: SUSY algebras and their particle representations; Weyl and Majorana spinors; Lagrangians of basic four-dimensional SUSY theories, both rigid SUSY and supergravity; supermultiplets of fields and superspace methods; renormalization properties, and the non-renormalization theorem; spontaneous breakdown of SUSY; and phenomenological SUSY theories. Some prior knowledge of Noether's theorem, derivation and use of Feynman rules, l-loop renormalization, and gauge theories is essential.
D. Z. Freedman

8.841 Electroweak Interactions
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 8.324
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
An introduction to the standard model of electroweak interactions and beyond; neutrino interactions and masses; the CKM matrix; lepton scattering off of necleons and nuclei; the search for the Higgs boson; supersymmetric extension of the standard model. Topics vary with instructor.
Staff

8.851 Effective Field Theory
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 8.324
Units: 3-0-9
Credit cannot also be received for8.S851
URL: http://web.mit.edu/physics/subjects/index.html
______
Covers the framework and tools of effective field theory, including: identifying degrees of freedom and symmetries; power counting expansions (dimensional and otherwise); field redefinitions, bottom-up and top-down effective theories; fine-tuned effective theories; matching and Wilson coefficients; reparameterization invariance; and advanced renormalization group techniques. Main examples are taken from particle and nuclear physics, including the Soft-Collinear Effective Theory.
I. Stewart

8.861 Advanced Topics in Superfluidity
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 8.324
Units: 3-0-9
______
Basic pairing theory, effective field theory and spontaneous symmetry breaking; well-established applications to liquid helium 3 as a warm-up; research will be explored including anisotropic superconductivity in heavy fermion systems and cuprates; color superconductivity in high-density QCD; and pairing in fermion systems with mismatched Fermi surfaces, including ultracold atom systems. Additional ideas needed to discuss the fractional quantum Hall effect will be reviewed, emphasizing its connection to conventional superfluidity, and pointing toward aspects of anyon behavior potentially relevant for quantum information processing.
Staff

8.871 Selected Topics in Theoretical Particle Physics
______

Not offered academic year 2016-2017Graduate (Fall, Spring) Can be repeated for credit
Prereq: 8.323
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______

8.872 Selected Topics in Theoretical Particle Physics
______

Not offered academic year 2016-2017Graduate (Fall, Spring) Can be repeated for credit
Prereq: 8.323
Units: 3-0-9
______
Presents topics of current interest in theoretical particle physics, with content varying from year to year. Subject not routinely offered; given when sufficient interest is indicated.
Staff

8.881, 8.882 Selected Topics in Experimental Particle Physics
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: 8.811
Units: 3-0-9
______
Presents topics of current interest in experimental particle physics, with content varying from year to year. Subject not routinely offered; given when sufficient interest is indicated.
Staff

Space Physics and Astrophysics

8.901 Astrophysics I
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Size and time scales. Historical astronomy. Astronomical instrumentation. Stars: spectra and classification. Stellar structure equations and survey of stellar evolution. Stellar oscillations. Degenerate and collapsed stars; radio pulsars. Interacting binary systems; accretion disks, x-ray sources. Gravitational lenses; dark matter. Interstellar medium: HII regions, supernova remnants, molecular clouds, dust; radiative transfer; Jeans' mass; star formation. High-energy astrophysics: Compton scattering, bremsstrahlung, synchrotron radiation, cosmic rays. Galactic stellar distributions and populations; Oort constants; Oort limit; and globular clusters.
Staff

8.902 Astrophysics II
______

Graduate (Fall)
Prereq: 8.901
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR11-12.30 (4-261) +final
______
Galactic dynamics: potential theory, orbits, collisionless Boltzmann equation, etc. Galaxy interactions. Groups and clusters; dark matter. Intergalactic medium; x-ray clusters. Active galactic nuclei: unified models, black hole accretion, radio and optical jets, etc. Homogeneity and isotropy, redshift, galaxy distance ladder. Newtonian cosmology. Roberston-Walker models and cosmography. Early universe, primordial nucleosynthesis, recombination. Cosmic microwave background radiation. Large-scale structure, galaxy formation.
M. Vogelsberger
Textbooks (Fall 2016)

8.913 Plasma Astrophysics I
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
______
Staff

8.914 Plasma Astrophysics II
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
For students interested in space physics, astrophysics, and plasma physics in general. Magnetospheres of rotating magnetized planets, ordinary stars, neutron stars, and black holes. Pulsar models: processes for slowing down, particle acceleration, and radiation emission; accreting plasmas and x-ray stars; stellar winds; heliosphere and solar wind- relevant magnetic field configuration, measured particle distribution in velocity space and induced collective modes; stability of the current sheet and collisionless processes for magnetic reconnection; theory of collisionless shocks; solitons; Ferroaro-Rosenbluth sheet; solar flare models; heating processes of the solar corona; Earth's magnetosphere (auroral phenomena and their interpretation, bowshock, magnetotail, trapped particle effects); relationship between gravitational (galactic) plasmas and electromagnetic plasmas. 8.913 deals with heliospheric, 8.914 with extra-heliospheric plasmas.
B. Coppi

8.921 Stellar Structure and Evolution
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Observable stellar characteristics; overview of observational information. Principles underlying calculations of stellar structure. Physical processes in stellar interiors; properties of matter and radiation; radiative, conductive, and convective heat transport; nuclear energy generation; nucleosynthesis; and neutrino emission. Protostars; the main sequence, and the solar neutrino flux; advanced evolutionary stages; variable stars; planetary nebulae, supernovae, white dwarfs, and neutron stars; close binary systems; and abundance of chemical elements.
Staff

8.942 Cosmology
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Thermal backgrounds in space. Cosmological principle and its consequences: Newtonian cosmology and types of "universes"; survey of relativistic cosmology; horizons. Overview of evolution in cosmology; radiation and element synthesis; physical models of the "early stages." Formation of large-scale structure to variability of physical laws. First and last states. Some knowledge of relativity expected. 8.962 recommended though not required.
M. Tegmark

8.952 Particle Physics of the Early Universe
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 8.323,Coreq: 8.324
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Basics of general relativity, standard big bang cosmology, thermodynamics of the early universe, cosmic background radiation, primordial nucleosynthesis, basics of the standard model of particle physics, electroweak and QCD phase transition, basics of group theory, grand unified theories, baryon asymmetry, monopoles, cosmic strings, domain walls, axions, inflationary universe, and structure formation.
A. Guth

8.962 General Relativity
______

Graduate (Spring)
Prereq: 18.03, 18.06, 8.07
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
The basic principles of Einstein's general theory of relativity, differential geometry, experimental tests of general relativity, black holes, and cosmology.
Staff

8.971 Astrophysics Seminar
______

Not offered academic year 2016-2017Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
URL: http://web.mit.edu/physics/subjects/index.html
______
Advanced seminar on current topics, with a different focus each term. Typical topics: astronomical instrumentation, numerical and statistical methods in astrophysics, gravitational lenses, neutron stars and pulsars.
Consult D. Chakrabarty

8.972 Astrophysics Seminar
______

Not offered academic year 2016-2017Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
URL: http://web.mit.edu/physics/subjects/index.html
______
Advanced seminar on current topics, with a different focus each term. Typical topics: gravitational lenses, active galactic nuclei, neutron stars and pulsars, galaxy formation, supernovae and supernova remnants, brown dwarfs, and extrasolar planetary systems. The presenter at each session is selected by drawing names from a hat containing those of all attendees. Offered if sufficient interest is indicated.
Consult D. Chakrabarty

8.981, 8.982 Selected Topics in Astrophysics
______

Not offered academic year 2017-2018Graduate (Spring) Can be repeated for credit
Prereq: Permission of Instructor
Units: 3-0-9 [P/D/F]
______
Topics of current interest, varying from year to year. Subject not routinely offered; given when sufficient interest is indicated.
Consult D. Chakrabarty

8.995 Practical Work Experience
(New)
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
For Course 8 students participating in off-campus work experiences in physics. Before registering for this subject, students must have an employment offer from a company or organization, must identify a Physics supervisor, and must receive prior approval from the Physics Department. Upon completion of the work, student must submit a letter from the employer describing the work accomplished, along with a substantive final report from the student approved by the MIT supervisor. Consult departmental academic office.
Consult N. Mavalvala
No required or recommended textbooks

8.S301 Special Subject: Physics
______

Graduate (Spring)
Prereq: Permission of instructor
Units arranged
______
Covers topics in Physics that are not offered in the regular curriculum. Limited enrollment; preference to Physics graduate students.
A. Lightman

8.S421 Special Subject: Physics
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Opportunity for group study of subjects in physics not otherwise included in the curriculum.
W. Ketterle
No required or recommended textbooks

8.THG Graduate Physics Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of an SM, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member.
Consult I. Stewart
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


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Produced: 26-SEP-2016 05:10 PMFall 2016 Course 9: Brain and Cognitive Sciences
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Course 9: Brain and Cognitive Sciences
Fall 2016


9.00 Introduction to Psychological Science
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 4-0-8
______
A survey of the scientific study of human nature, including how the mind works, and how the brain supports the mind. Topics include the mental and neural bases of perception, emotion, learning, memory, cognition, child development, personality, psychopathology, and social interaction. Consideration of how such knowledge relates to debates about nature and nurture, free will, consciousness, human differences, self, and society.
J. D. Gabrieli

9.01 Introduction to Neuroscience
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Physics II (GIR) or permission of instructor
Units: 4-0-8
Lecture: MW1-2.30 (46-3002) Recitation: W EVE (7 PM) (56-162) or R EVE (7 PM) (56-162) or F11 (46-1015) or F2 (46-1015) +final
______
Introduction to the mammalian nervous system, with emphasis on the structure and function of the human brain. Topics include the function of nerve cells, sensory systems, control of movement, learning and memory, and diseases of the brain.
M. Bear
Textbooks (Fall 2016)

9.011 Systems Neuroscience
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 6-0-12
Lecture: MWF2-4 (46-3015) +final
______
Survey of brain and behavioral studies. Examines principles underlying the structure and function of the nervous system, with a focus on systems approaches. Topics include development of the nervous system and its connections, sensory systems of the brain, the motor system, higher cortical functions, and behavioral and cellular analyses of learning and memory. Preference to first-year graduate students in BCS.
M. Wilson, E. K. Miller
No required or recommended textbooks

9.012 Cognitive Science
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 6-0-12
______
Intensive survey of cognitive science. Topics include visual perception, language, memory, cognitive architecture, learning, reasoning, decision-making, and cognitive development. Topics covered from behavioral, computational, and neural perspectives.
E. Gibson, P. Sinha, J. Tenenbaum

9.013[J] Molecular and Cellular Neuroscience Core II
______

Graduate (Spring)
(Same subject as7.68[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Survey and primary literature review of major areas in molecular and cellular neurobiology. Covers genetic neurotrophin signaling, adult neurogenesis, G-protein coupled receptor signaling, glia function, epigenetics, neuronal and homeostatic plasticity, neuromodulators of circuit function, and neurological/psychiatric disease mechanisms. Includes lectures and exams, and involves presentation and discussion of primary literature. 9.015 recommended, though the core subjects can be taken in any sequence.
G. Feng, L.-H. Tsai

9.014 Quantitative Methods and Computational Models in Neurosciences
(New)
______

Graduate (Fall)
Prereq: None
Units: 3-1-8
Lecture: W11,F10-12 (46-3015) Lab: M11 (46-3015)
______
Provides theoretical background and practical skills needed to analyze and model neurobiological observations at the molecular, systems and cognitive levels. Develops an intuitive understanding of mathematical tools and computational techniques which students apply to analyze, visualize and model research data using MATLAB programming. Topics include linear systems and operations, dimensionality reduction (e.g., PCA), Bayesian approaches, descriptive and generative models, classification and clustering, and dynamical systems.
M. Jazayeri, D. Zysman
No required or recommended textbooks

9.015[J] Molecular and Cellular Neuroscience Core I
______

Graduate (Fall)
(Same subject as7.65[J])
Prereq: None
Units: 3-0-9
Lecture: TR1-2.30 (46-4062)
______
Survey and primary literature review of major topic areas in molecular and cellular neurobiology. Covers neurogenomics, nervous system formation, axonal pathfinding, cytoskeletal regulation, synapse formation, neurotransmitter release, and cellular neurophysiology. Includes lectures and weekly paper write-ups, together with student presentations and discussion of primary literature. A final two-page research write-up is also due at the end of the term.
J. T. Littleton, H. Sive, F. Gertler
No required or recommended textbooks

9.04 Sensory Systems
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 9.01 or permission of instructor
Units: 3-0-9
______
Examines the neural bases of sensory perception. Focuses on physiological and anatomical studies of the mammalian nervous system as well as behavioral studies of animals and humans. Topics include visual pattern, color and depth perception, auditory responses and sound localization, olfactory and somatosensory perception.
G. Choi

9.07 Statistics for Brain and Cognitive Science
______

Undergrad (Fall)
Prereq: 9.40
Units: 4-0-8
Lecture: MW9.30-11 (46-5056) Recitation: F11 (46-5056) +final
______
Provides students with the basic tools for analyzing experimental data, properly interpreting statistical reports in the literature, and reasoning under uncertain situations. Topics organized around three key theories: probability, statistical, and the linear model. Probability theory covers axioms of probability, discrete and continuous probability models, law of large numbers, and the Central Limit Theorem. Statistical theory covers estimation, likelihood theory, Bayesian methods, bootstrap and other Monte Carlo methods, as well as hypothesis testing, confidence intervals, elementary design of experiments principles and goodness-of-fit. The linear model theory covers the simple regression model and the analysis of variance. Places equal emphasis on theory, data analyses, and simulation studies.
E. N. Brown
No required or recommended textbooks

9.073[J] Statistics for Neuroscience Research
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject asHST.460[J])
Prereq: Permission of instructor
Units: 3-0-9
______
A survey of statistical methods for neuroscience research. Core topics include introductions to the theory of point processes, the generalized linear model, Monte Carlo methods, Bayesian methods, multivariate methods, time-series analysis, spectral analysis and state-space modeling. Emphasis on developing a firm conceptual understanding of the statistical paradigm and statistical methods primarily through analyses of actual experimental data.
E. N. Brown

9.09[J] Cellular and Molecular Neurobiology
______

Undergrad (Spring)
(Same subject as7.29[J])
Prereq: 7.05 or 9.01
Units: 4-0-8
______
Introduction to the structure and function of the nervous system. Emphasizes the cellular properties of neurons and other excitable cells. Includes the structure and biophysical properties of excitable cells, synaptic transmission, neurochemistry, neurodevelopment, integration of information in simple systems, and detection and information coding during sensory transduction.
T. Littleton, M. Heiman

9.10 Cognitive Neuroscience
______

Undergrad (Spring)
Prereq: 9.01
Units: 3-0-9
______
Explores the cognitive and neural processes that support attention, vision, language, social cognition, music understanding, emotion, motor control, and memory. Begins with the fundamental behavioral phenomena, then progresses to models based on brain systems in humans and animals, and ultimately models based on populations of neurons. Includes examples of clinical conditions and case studies in patients. Students prepare presentations summarizing journal articles.
R. Desimone, E. K. Miller

9.110[J] Nonlinear Control
______

Graduate (Spring)
(Same subject as2.152[J])
Prereq: 2.151, 6.241, 16.31, or permission of instructor
Units: 3-0-9
______
Introduction to nonlinear control and estimation in physical and biological systems. Nonlinear stability theory, Lyapunov analysis, Barbalat's lemma. Feedback linearization, differential flatness, internal dynamics. Sliding surfaces. Adaptive nonlinear control and estimation. Multiresolution bases, nonlinear system identification. Contraction analysis, differential stability theory. Nonlinear observers. Asynchronous distributed computation and learning. Concurrent synchronization, polyrhythms. Monotone nonlinear systems. Emphasizws application to physical systems (robots, aircraft, spacecraft, underwater vehicles, reaction-diffusion processes, machine vision, oscillators, internet), machine learning, computational neuroscience, and systems biology. Includes term projects.
J.-J. E. Slotine

9.12 Experimental Molecular Neurobiology
______

Undergrad (Spring) Institute Lab
Prereq: 9.01, Biology (GIR)
Units: 2-4-6
______
Experimental techniques in cellular and molecular neurobiology. Designed for students without previous experience in techniques of cellular and molecular biology. Experimental approaches include DNA manipulation, molecular clonging, protein biochemistry, dissection and culture of brain cells, synaptic protein analysis, immunocytochemistry, and fluorescent microscopy. One lab session plus one paper review session per week. Instruction and practice in written communication provided. Enrollment limited.
Y. Lin, G. Choi

9.123[J] Neurotechnology in Action
______

Graduate (Fall)
(Same subject as20.203[J])
Prereq: Permission of instructor
Units: 3-6-3
Lecture: TR2.30-4 (46-4062)
______
Offers a fast-paced introduction to numerous laboratory methods at the forefront of modern neurobiology. Comprises a sequence of modules focusing on neurotechnologies that are developed and used by MIT research groups. Each module consists of a background lecture and 1-2 days of firsthand laboratory experience. Topics typically include optical imaging, optogenetics, high throughput neurobiology, MRI/fMRI, advanced electrophysiology, viral and genetic tools, and connectomics.
A. Jasanoff, E. Boyden, M. Jonas
No required or recommended textbooks

9.14 Brain Structure and its Origins
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 9.01
Units: 3-0-9
______
Provides an introduction to functional neuroanatomy with a focus on mammals, aided by studies of comparative neuroanatomy and evolution and of brain development. Topics include early steps to a central nervous system, basic patterns of brain and spinal cord connections, regional development and differentiation, regeneration, motor and sensory pathways and structures, systems underlying motivations, innate action patterns, formation of habits, and various cognitive functions. Review of lab techniques. Optional brain dissections.
G. E. Schneider

9.15 Neural Circuits, Neuromodulatory, and Neuroendocrine Systems
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 9.01 or permission of instructor
Units: 3-0-9
______
Studies how neural circuits give rise to behavior, and how neuromodulatory systems and pharmacological intervention can influence these processes. Lectures and selected publications cover the fundamentals of neuropharmacology, neuromodulatory systems, and approaches to understand circuit mechanisms. Provides a historical view of various neurotransmitter or neuromodulatory systems as well as an understanding of how research is conducted at the forefront of neuroscience today. Instruction and practice in oral and written communication provided. Students present a primary research article and also submit a research proposal which they have the opportunity to revise based on feedback.
K. Tye

9.16 Cellular Neurophysiology
______

Undergrad (Fall)
(Subject meets with9.160)
Prereq: 9.40
Units: 3-0-9
Lecture: TR11-12.30 (46-4062) +final
______
Surveys the mechanisms of neuronal communication. Covers ion channels in excitable membrane, single cell computation, synaptic transmission, and synaptic plasticity. Correlates the properties of ion channels and synaptic transmission with their physiological function. Discusses the organizational principles for the formation of functional neural networks at synaptic and cellular levels. Involves discussion of primary literature. Students taking graduate version complete additional assignments.
W. Xu
Textbooks (Fall 2016)

9.160 Cellular Neurophysiology
(New)
______

Graduate (Fall)
(Subject meets with9.16)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR11-12.30 (46-4062) +final
______
Surveys the mechanisms of neuronal communication. Covers ion channels in excitable membrane, single cell computation, synaptic transmission, and synaptic plasticity. Correlates the properties of ion channels and synaptic transmission with their physiological function. Discusses the organizational principles for the formation of functional neural networks at synaptic and cellular levels. Involves discussion of primary literature. Students taking graduate version complete additional assignments.
W. Xu
Textbooks (Fall 2016)

9.17 Systems Neuroscience Laboratory
______

Undergrad (Fall) Institute Lab
Prereq: 9.40 or permission of instructor;Coreq: 9.07
Units: 2-4-6
Lecture: M4 (46-1015) Lab: R1-5 (46-1024) Recitation: T9 (46-1015)
______
Consists of a series of laboratories designed to give students experience with basic techniques for conducting systems neuroscience research. Includes sessions on anatomical, neurophysiological, and data acquisition and analysis techniques, and how these techniques are used to study nervous system function. Involves the use of experimental animals. Assignments include weekly preparation for lab sessions, two major lab reports and a series of basic computer programming tutorials (MATLAB). Instruction and practice in written communication provided. Enrollment limited.
M. Wilson, M. Harnett
No required or recommended textbooks

9.173[J] Noninvasive Imaging in Biology and Medicine
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as20.483[J],22.56[J],HST.561[J])
Prereq: 18.03, 8.03, or permission of instructor
Units: 3-0-9
______
Background in the theory and application of noninvasive imaging methods in biology and medicine, with emphasis on neuroimaging. Focuses on the modalities most frequently used in scientific research (x-ray CT, PET/SPECT, MRI, and optical imaging), and includes discussion of molecular imaging approaches used in conjunction with these scanning methods. Lectures are supplemented by in-class discussions of problems in research and demonstrations of imaging systems.
A. Jasanoff

9.175[J] Robotics
______

Graduate (Spring)
(Same subject as2.165[J])
Prereq: 2.151 or permission of instructor
Units: 3-0-9
______
Dynamic analysis, design, and control of robots. Forward and inverse kinematics and dynamics of multi-input, multi-output rigid body systems. Computed torque control. Adaptive control. System identification. Force feedback, adaptive visual servoing. Task planning, teleoperation. Elements of biological planning and control. Motor primitives, entrainment, locomotion, active sensing, binding models. Term projects.
J.-J. E. Slotine, H. Asada

9.18[J] Developmental Neurobiology
______

Undergrad (Spring)
(Same subject as 7.49[J])
(Subject meets with7.69[J],9.181[J])
Prereq: 9.01, 7.03, 7.05, or permission of instructor
Units: 3-0-9
______

9.181[J] Developmental Neurobiology
______

Graduate (Spring)
(Same subject as7.69[J])
(Subject meets with 7.49[J],9.18[J])
Prereq: 9.011 or permission of instructor
Units: 3-0-9
______
Considers molecular control of neural specification, formation of neuronal connections, construction of neural systems, and the contributions of experience to shaping brain structure and function. Topics include: neural induction and pattern formation, cell lineage and fate determination, neuronal migration, axon guidance, synapse formation and stabilization, activity-dependent development and critical periods, development of behavior. In addition to final exam, analysis and presentation of research papers required for final grade. Students taking graduate version complete additional assignments. Students taking graduate version complete additional readings that will be addressed in their mid-term and final exams.
E. Nedivi, M. Heiman

9.20 Animal Behavior
______

Undergrad (Fall) HASS Social Sciences
Prereq: 9.00
Units: 3-0-9
Lecture: MWF4 (46-3310) +final
______
Reviews studies of animal behavior to stress major ideas and principles, with emphasis on concepts developed in ethology and sociobiology. Examines foraging and feeding, defensive and aggressive behavior, courtship and reproduction, migration and navigation, as well as various social activities and communication. Considers inherited abilities, motivational systems and motor patterns, together with influences of various types of learning. Reviews both field and laboratory studies, and considers human behavior in the context of primate studies.
G. E. Schneider
Textbooks (Fall 2016)

9.24 Disorders and Diseases of the Nervous System
______

Undergrad (Spring)
Prereq: 9.00, 9.01, 9.09
Units: 3-0-9
______
Topics examined include regional functional anatomy of the CNS; brain systems and circuits; neurodevelopmental disorders including autism; neuropsychiatric disorders such as schizophrenia; neurodegenerative diseases such as Parkinson's and Alzheimer's; autoimmune disorders such as multiple sclerosis; gliomas. Emphasis on diseases for which a molecular mechanism is understood. Diagnostic criteria, clinical and pathological findings, genetics, model systems, pathophysiology, and treatment are discussed for individual disorders and diseases.
M. Sur

9.26[J] Principles and Applications of Genetic Engineering for Biotechnology and Neuroscience
______

Undergrad (Spring)
(Same subject as20.205[J])
Prereq: 7.28, 7.32, or 20.020; 9.01 or 9.09
Units: 3-0-9
______
Covers principles underlying current and future genetic engineering approaches, ranging from single cellular organisms to whole animals. Focuses on development and invention of technologies for engineering biological systems at the genomic level, and applications of engineered biological systems for medical and biotechnological needs, with particular emphasis on genetic manipulation of the nervous system. Design projects by students.
F. Zhang

9.272[J] Topics in Neural Signal Processing
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject asHST.576[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Presents signal processing and statistical methods used to study neural systems and analyze neurophysiological data. Topics include state-space modeling formulated using the Bayesian Chapman-Kolmogorov system, theory of point processes, EM algorithm, Bayesian and sequential Monte Carlo methods. Applications include dynamic analyses of neural encoding, neural spike train decoding, studies of neural receptive field plasticity, algorithms for neural prosthetic control, EEG and MEG source localization. Students should know introductory probability theory and statistics. Alternate years.
E. N. Brown

9.28 Current Topics in Developmental Neurobiology
______

Undergrad (Spring)
Prereq: None.Coreq: 9.18
Units: 3-0-12
______
Considers recent advances in the field of developmental neurobiology based on primary research articles that address molecular control of neural specification, formation of neuronal connections, construction of neural systems, and the contributions of experience to shaping brain structure and function. Also considers new techniques and methodologies as applied to the field. Students critically analyze articles and prepare concise and informative presentations based on their content. Instruction and practice in written and oral communication provided. Requires class participation, presentations, and final exam.
E. Nedivi

9.285[J] Neural Coding and Perception of Sound
______

Graduate (Spring)
(Same subject asHST.723[J])
Prereq: Permission of instructor
Units: 3-1-8
______
Neural structures and mechanisms mediating the detection, localization, and recognition of sounds. Discussion of how acoustic signals are coded by auditory neurons, the impact of these codes on behavioral performance, and the circuitry and cellular mechanisms underlying signal transformations. Topics include temporal coding, neural maps and feature detectors, learning and plasticity, and feedback control. General principles are conveyed by theme discussions of auditory masking, sound localization, musical pitch, cochlear implants, and auditory scene analysis. Follows Harvard FAS calendar.
B. Delgutte, M. C. Brown, J. McDermott, D. Polley

9.301[J] Neural Plasticity in Learning and Memory
______

Graduate (Spring)
(Same subject as7.98[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://web.mit.edu/7.98/
______
Examination of the role of neural plasticity during learning and memory of invertebrates and mammals. Detailed critical analysis of the current literature of molecular, cellular, genetic, electrophysiological, and behavioral studies. Student-directed presentations and discussions of original papers supplemented by introductory lectures. Juniors and seniors require instructor's permission.
S. Tonegawa, W. Quinn

9.31 Neurobiology of Learning and Memory
______

Undergrad (Fall)
Prereq: 9.01
Units: 4-0-8
Lecture: MW10.30-12 (46-5193) Recitation: F10.30 (46-5193)
______
Surveys the mechanisms supporting plasticity in neurons, focusing on how it contributes to learning in several systems. Examines cellular forms of associative plasticity, including long-term potentiation and depression, homeostatic plasticity, and depotentiation. Relates these phenomena to associative memory in animal systems and humans. Completion of 9.09 recommended.
M. Constantine-Paton
Textbooks (Fall 2016)

9.32 Genes, Circuits, and Behavior
______

Undergrad (Spring)
Prereq: 9.09, 9.10, 9.16, or 9.18
Units: 3-0-9
______
Focuses on understanding molecular and cellular mechanisms of circuitry development, function and plasticity, and their relevance to normal and abnormal behaviors/psychiatric disorders. Highlights cutting-edge technologies for neuroscience research. Students build professional skills through presentations and critical evaluation of original research papers.
G. Feng

9.322[J] Genetic Methods in Neurobiology
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as7.67[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://mit.edu/7.67j/
______
Presents selected topics in which genetic analysis informs neurobiological issues, including action potential conduction and synaptic release in Drosophila, axon guidance in nematodes and Drosophila, olfaction and orienting behavior in nematodes. Studies hippocampal and cortical circuitry and function in mice, as well as genetically-determined and genetically-influenced human traits and diseases. Reviews methods such as mutagenesis, gene knockouts and transgene constructs, tissue-specific expression vectors, optically, chemically and thermally-inducible gene activation and inactivation.
W. G. Quinn

9.33 Your Brain: A User's Guide
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Elective
Prereq: None
Units: 3-0-9
______
Provides students with perspective on brain functions and behaviors of particular relevance to individuals their age. Using library databases, students conduct scholarly research and compare the attitudes conveyed in magazines and newspapers with facts from neurobiology textbooks, scientific reviews, and basic research articles. Each student presents and leads a discussion on a topic related to a behavior of his or her choosing. Preference to freshmen and non-Course 9 majors; limited to 17.
M. Constantine-Paton

9.34[J] Biomechanics and Neural Control of Movement
______

Graduate (Spring)
(Same subject as2.183[J])
(Subject meets with2.184)
Prereq: 2.004, 2.04A, or permission of instructor
Units: 3-0-9
______
Quantitative knowledge of human movement behavior is important in a growing number of engineering applications (medical and rehabilitation technology, athletic and military equipment, human-computer interaction, vehicle performance, etc.). Presents a quantitative, model-based description of how biomechanical and neural factors interact in human sensory-motor behavior, focusing mainly on the upper limbs. Students survey recent literature on how motor behavior is controlled, comparing biological and robotic approaches to similar tasks. Topics may include a review of relevant neural, muscular and skeletal physiology, neural feedback and "equilibrium-point" theories, co-contraction strategies, impedance control, kinematic redundancy, optimization, intermittency, contact tasks and tool use. Students taking the graduate version will complete additional assignments.
N. Hogan

9.35 Perceptual Systems
______

Undergrad (Spring)
Prereq: 9.00, 9.01; or permission of instructor
Units: 4-0-8
______
Studies how the senses work and how physical stimuli are transformed into signals in the nervous system. Examines how the brain uses those signals to make inferences about the world, and uses illusions and demonstrations gain insight into those inferences. Emphasizes audition and vision, with some discussion of touch, taste, and smell. Provides experience with psychophysical methods.
J. McDermott

9.357 Current Topics in Vision Science
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-7
______
Advanced seminar on issues of current interest in human and machine vision. Topics vary from year to year. Participants discuss current literature as well as their ongoing research.
E. H. Adelson

9.40 Introduction to Neural Computation
______

Undergrad (Spring)
Prereq: 6.0002, 9.01
Units: 4-0-8
______
Introduces quantitative approaches to understanding brain and cognitive functions. Topics include mathematical description of neurons, the response of neurons to sensory stimuli, simple neuronal networks, statistical inference and decision making. Also covers foundational quantitative tools of data analysis in neuroscience: correlation, convolution, spectral analysis, principal components analysis. Mathematical concepts include simple differential equations and linear algebra.
M. Fee

9.41 Research and Communication in Neuroscience and Cognitive Science
______

Undergrad (Fall)
Prereq: 9.URG, permission of instructor
Units: 2-12-4
Lecture: M EVE (7-9 PM) (46-5056) Lab: TBA
______
Emphasizes research and scientific communication. Instruction and practice in written and oral communication provided. Based on results of his/her UROP research, each student creates a full-length paper and a poster as part of an oral presentation at the end of the term. Other assignments include peer editing and reading/critiquing published research papers. Prior to starting class, students must have collected enough data from their UROP research projects to write a paper. Limited to juniors and seniors.
L. Schulz
No textbook information available

9.42 The Brain and Its Interface with the Body
(New)
______

Undergrad (Spring)
Prereq: 7.28, 9.09, or permission of instructor
Units: 3-0-9
______
Covers a range of topics, such as brain-immune system interaction, the gut-brain axis, and bioengineering approaches for studying the brain and its interactions with different organs. Explores how these interactions may be involved in nervous system disease processes.
F. Zhang

9.422[J] Principles of Neuroengineering
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as20.452[J],MAS.881[J])
(Subject meets with20.352)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://neuro.media.mit.edu/classes/prinneuro/
______
Covers how to innovate technologies for brain analysis and engineering, for accelerating the basic understanding of the brain, and leading to new therapeutic insight and inventions. Focuses on using physical, chemical and biological principles to understand technology design criteria governing ability to observe and alter brain structure and function. Topics include optogenetics, noninvasive brain imaging and stimulation, nanotechnologies, stem cells and tissue engineering, and advanced molecular and structural imaging technologies. Includes design projects. Designed for students with engineering maturity who are ready for design. Students taking graduate version complete additional assignments.
E. S. Boyden, III

9.455[J] Revolutionary Ventures: How to Invent and Deploy Transformative Technologies
______

Graduate (Fall)
(Same subject as15.128[J],20.454[J],MAS.883[J])
Prereq: Permission of instructor
Units: 2-0-7
URL: http://neuro.media.mit.edu/classes/neuroven/
Lecture: R2-4 (E15-341)
______
Seminar on envisioning and building ideas and organizations to accelerate engineering revolutions. Focuses on emerging technology domains, such as neurotechnology, imaging, cryotechnology, gerontechnology, and bio-and-nano fabrication. Draws on historical examples as well as live case studies of existing or emerging organizations, including labs, institutes, startups, and companies. Goals range from accelerating basic science to developing transformative products or therapeutics. Each class is devoted to a specific area, often with invited speakers, exploring issues from the deeply technical through the strategic. Individually or in small groups, students prototype new ventures aimed at inventing and deploying revolutionary technologies.
J. Bonsen, J. Jacobson
No textbook information available

9.46 Neuroscience of Morality
______

Undergrad (Fall)
Prereq: 9.00, 9.01; 9.10, 9.20, or 9.85
Units: 3-0-9
Lecture: MW10.30-12 (46-1015) +final
______
Advanced seminar that covers both classic and cutting-edge primary literature from psychology and the neuroscience of morality. Addresses questions about how the human brain decides which actions are morally right or wrong (including neural mechanisms of empathy and self-control), how such brain systems develop over childhood and differ across individuals and cultures, and how they are affected by brain diseases (such as psychopathy, autism, tumors, or addiction). Instruction and practice in written and oral communication provided. Limited to 24.
R. Saxe
No required or recommended textbooks

9.48[J] Philosophical Issues in Brain Science
______

Undergrad (Fall) HASS Humanities Communication Intensive HASS
Not offered regularly; consult department
(Same subject as24.08[J])
Prereq: None
Units: 3-0-9
______
An introduction to some central philosophical questions about the mind, specifically those intimately connected with contemporary psychology and neuroscience. Discussions focus on arguments over innate concepts; 'mental images' as pictures in the head; whether color is in the mind or in the world; and whether there can be a science of consciousness. Explains the relevant parts of psychology and neuroscience as the subject proceeds.
A. Byrne


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Course 9: Brain and Cognitive Sciences
Fall 2016


9.50 Research in Brain and Cognitive Sciences
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: 9.00, permission of instructor
Units: 0-12-0
TBA.
______
Laboratory research in brain and cognitive science, using physiological, anatomical, pharmacological, developmental, behavioral, and computational methods. Each student carries out an experimental study under the direction of a member of the faculty. Project must be approved in advance by the faculty supervisor and the Director of the Undergraduate Program. Written presentation of results is required.
Consult L. Schulz
No textbook information available

9.520[J] Statistical Learning Theory and Applications
______

Graduate (Fall)
(Same subject as6.860[J])
Prereq: 6.867, 6.041B, 18.06, or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/9.520/www/
Lecture: MW1-2.30 (46-3310)
______
Provides students with the knowledge needed to use and develop advanced machine learning solutions to challenging problems. Covers foundations and recent advances of machine learning in the framework of statistical learning theory. Focuses on regularization techniques key to high-dimensional supervised learning. Starting from classical methods such as regularization networks and support vector machines, addresses state-of-the-art techniques based on principles such as geometry or sparsity, and discusses a variety of algorithms for supervised learning, feature selection, structured prediction, and multitask learning. Also focuses on unsupervised learning of data representations, with an emphasis on hierarchical (deep) architectures.
T. Poggio, L. Rosasco
No required or recommended textbooks

9.523[J] Aspects of a Computational Theory of Intelligence
______

Graduate (Fall)
(Same subject as6.861[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: F11-2 (46-3189)
______
Integrates neuroscience, cognitive and computer science to explore the nature of intelligence, how it is produced by the brain, and how it can be replicated in machines. Discusses an array of current research connected through an overarching theme of how it contributes to a computational account of how humans analyze dynamic visual imagery to understand objects and actions in the world.
T. Poggio, S. Ullman
No required or recommended textbooks

9.54 Computational Aspects of Biological Learning
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 9.40
Units: 3-0-9
______
Takes a computational approach to learning in the brain by neurons and synapses. Examines supervised and unsupervised learning as well as possible biological substrates, including Hebb synapses and the related topics of Oja flow and principal components analysis. Discusses hypothetical computational primitives in the nervous system, and the implications for unsupervised learning algorithms underlying the development of tuning properties of cortical neurons. Also focuses on a broad class of biologically plausible learning strategies.
T. Poggio, S. Ullman

9.56[J] Abnormal Language
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject as24.907[J])
Prereq: 24.900 or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduction to the linguistic study of language pathology, concentrating on experimental approaches and theoretical explanations. Discussion of Specific Language Impairment, Down syndrome, William's syndrome, autism, normal aging, Parkinson's disease, Alzheimer's disease, hemispherectomy, and aphasia. Focuses on the comparison of linguistic abilities among these syndromes, while drawing clear comparisons with first- and second-language acquisition. Topics include the lexicon, morphology, syntax, semantics, and pragmatics. Relates the lost linguistic abilities in these syndromes to properties of the brain.
K. Wexler

9.583[J] Functional Magnetic Resonance Imaging: Data Acquisition and Analysis
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject asHST.583[J])
Prereq: 18.05; 18.06 or permission of instructor
Units: 2-3-7
______
Provides background necessary for designing, conducting, and interpreting fMRI studies in the human brain. Covers in depth the physics of image encoding, mechanisms of anatomical and functional contrasts, the physiological basis of fMRI signals, cerebral hemodynamics, and neurovascular coupling. Also covers design methods for stimulus-, task-driven and resting-state experiments, as well as workflows for model-based and data-driven analysis methods for data. Instruction in brain structure analysis and surface- and region-based analyses. Laboratory sessions include data acquisition sessions at the 3 Tesla MRI scanner at MIT and the Connectom and 7 Tesla scanners at the MGH/HST Martinos Center, as well as hands-on data analysis workshops. Introductory or college-level neurobiology, physics, and signal processing are helpful.
S. Whitfield-Gabrieli, J. Polimeni, A. Yendiki

9.59[J] Laboratory in Psycholinguistics
______

Undergrad (Spring) Institute Lab
(Same subject as24.905[J])
Prereq: 9.00 or 24.900
Units: 3-3-6
______
Hands-on experience designing, conducting, analyzing, and presenting experiments on the structure and processing of human language. Focuses on constructing, conducting, analyzing, and presenting an original and independent experimental project of publishable quality. Develops skills in reading and writing scientific research reports in cognitive science, including evaluating the methods section of a published paper, reading and understanding graphical displays and statistical claims about data, and evaluating theoretical claims based on experimental data. Instruction and practice in oral and written communication provided.
E. Gibson

9.601[J] Language Acquisition I
______

Graduate (Fall)
(Same subject as24.949[J])
Prereq: Permission of instructor
Units: 3-0-6
Lecture: M2-5 (32-D461)
______
Lectures, reading, and discussion of current theory and data concerning the psychology and biology of language acquisition. Emphasizes learning of syntax, semantics, and morphology, together with some discussion of phonology, and especially research relating grammatical theory and learnability theory to empirical studies of children.
L. Koring
No textbook information available

9.611[J] Natural Language and the Computer Representation of Knowledge
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as6.863[J])
Prereq: 6.034
Units: 3-3-6
______
Explores the relationship between computer representation of knowledge and the structure of natural language. Emphasizes development of analytical skills necessary to judge the computational implications of grammatical formalisms, and uses concrete examples to illustrate particular computational issues. Efficient parsing algorithms for context-free grammars; Treebank grammars and statistical parsing. Question answering systems. Extensive laboratory work on building natural language processing systems.
R. C. Berwick

9.63 Laboratory in Visual Cognition
______

Not offered academic year 2016-2017Undergrad (Fall) Institute Lab
Prereq: 9.00
Units: 2-1-9
Subject Cancelled Subject Cancelled
______
Teaches principles of experimental methods in human visual perception and attention, including how to design, conduct, analyze, and present experiments in visual cognition. Combines lectures and hands-on experimental exercises. Requires two experimental projects, at least one of which is conducted independently; the other may be done as part of a team. Assignments include individual reports on experimental designs, written articles, and presentations critiquing three team experiments observed in class. Instruction and practice in written and oral communication provided. Experience with MATLAB is recommended. Limited to 16.
P. Sinha
No required or recommended textbooks

9.65 Cognitive Processes
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Social Sciences
Prereq: 9.00
Units: 3-0-9
______
Introduction to human information processing and learning. Topics include the nature of mental representation and processing, memory and learning, pattern recognition, attention, imagery and mental codes, concepts and prototypes, as well as reasoning and problem-solving.
M. C. Potter

9.66[J] Computational Cognitive Science
______

Undergrad (Fall)
(Same subject as6.804[J])
(Subject meets with9.660)
Prereq: 6.008, 6.036, 6.041B, 9.40, 18.05, or permission of instructor
Units: 3-0-9
9.66: Lecture: TR1-2.30 (46-3189)
______
Introduction to computational theories of human cognition. Focus on principles of inductive learning and inference, and the representation of knowledge. Computational frameworks covered include Bayesian and hierarchical Bayesian models; probabilistic graphical models; nonparametric statistical models and the Bayesian Occam's razor; sampling algorithms for approximate learning and inference; and probabilistic models defined over structured representations such as first-order logic, grammars, or relational schemas. Applications to understanding core aspects of cognition, such as concept learning and categorization, causal reasoning, theory formation, language acquisition, and social inference. Graduate students complete a final project.
J. Tenenbaum
9.66: No required or recommended textbooks

9.660 Computational Cognitive Science
______

Graduate (Fall)
(Subject meets with6.804[J],9.66[J])
Prereq: Permission of instructor
Units: 3-0-9
9.660: Lecture: TR1-2.30 (46-3189)
______
Introduction to computational theories of human cognition. Focuses on principles of inductive learning and inference, and the representation of knowledge. Computational frameworks include Bayesian and hierarchical Bayesian models, probabilistic graphical models, nonparametric statistical models and the Bayesian Occam's razor, sampling algorithms for approximate learning and inference, and probabilistic models defined over structured representations such as first-order logic, grammars, or relational schemas. Applications to understanding core aspects of cognition, such as concept learning and categorization, causal reasoning, theory formation, language acquisition, and social inference. Graduate students complete a final project.
J. Tenenbaum
9.660: No textbook information available

9.71 Functional MRI Investigations of the Human Brain
______

Undergrad (Fall)
Prereq: 9.07, 18.05, or permission of instructor
Units: 3-0-9
Lecture: T EVE (7-10 PM) (46-3015)
______
Covers design and interpretation of fMRI experiments, and the relationship between fMRI and other techniques. Focuses on localization of cognitive function in the human brain. Students write papers and give presentations, explain and critique published papers, and design but do not conduct their own fMRI experiments. Upon completion, students should be able to understand and critique published fMRI papers and have a good grasp of what is known about localization of cognitive function from fMRI. Instruction and practice in written and oral communication provided. Limited to 12.
N. G. Kanwisher
No required or recommended textbooks

9.77 Computational Perception
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 9.00, 9.40; 9.35 or 9.65
Units: 3-0-9
______
Begins with a review of the experimental paradigms, findings and theories used to evaluate the capabilities and limits of human visual perception. Assesses how knowledge of human perception may be used to guide machine vision systems. Second part of the subject focuses on models in computational perception. Describes how computer vision systems can perform image analysis and synthesis; face, object and scene perception; texture synthesis, segmentation, and navigation. Introduces various simulation methods. A MATLAB-based project in computational perception is required. Limited to 8.
E. Adelson

9.822[J] Psychology and Economics
______

Graduate (Spring)
(Same subject as14.137[J])
Prereq: None
Units: 4-0-8
______
Examines "psychology appreciation" for economics students. Aims to enhance knowledge and intuition about psychological processes in areas relevant to economics. Increases understanding of psychology as an experimental discipline, with its own distinct rules and style of argument. Topics include self-knowledge, cognitive dissonance, self-deception, emotions, social norms, self-control, learning, mental accounting, memory, individual and group behavior, and some personality and psycho-analytic models. Within each of these topics, we showcase effective and central experiments and discuss their role in the development of psychological theory. Term paper required.
D. Prelec

9.85 Infant and Early Childhood Cognition
______

Undergrad (Fall) HASS Social Sciences
Prereq: 9.00
Units: 3-0-9
Lecture: TR1-2.30 (46-3002)
______
Introduction to cognitive development focusing on childrens' understanding of objects, agents, and causality. Develops a critical understanding of experimental design. Discusses how developmental research might address philosophical questions about the origins of knowledge, appearance and reality, and the problem of other minds. Provides instruction and practice in written communication as necessary to research in cognitive science (including critical reviews of journal papers, a literature review and an original research proposal), as well as instruction and practice in oral communication in the form of a poster presentation of a journal paper.
L. Schulz
No required or recommended textbooks

9.901 Responsible Conduct in Science
______

Graduate (IAP)
Prereq: None
Units: 1-0-1 [P/D/F]
______
Provides instruction and dialogue on practical ethical issues relating to the responsible conduct of human and animal research in the brain and cognitive sciences. Specific emphasis on topics relevant to young researchers including data handling, animal and human subjects, misconduct, mentoring, intellectual property, and publication. Preliminary assigned readings and initial faculty lecture followed by discussion groups of four to five students each. A short written summary of the discussions submitted at the end of each class. See IAP Guide for registration information.
M. Wilson

9.91 Independent Study in Brain and Cognitive Sciences
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: 9.00 and any other two subjects in Brain and Cognitive Sciences; permission of instructor
Units arranged
TBA.
______
Individual study of a topic under the direction of a member of the faculty.
Consult Staff
No textbook information available

9.919 Teaching Brain and Cognitive Sciences
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
For teaching assistants in Brain and Cognitive Sciences, in cases where teaching assignment is approved for academic credit by the department.
Staff
No textbook information available

9.921 Research in Brain and Cognitive Sciences
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Guided research under the sponsorship of individual members of the faculty. Ordinarily restricted to candidates for the doctoral degree in Course 9.
Staff
No textbook information available

9.941 Graduate Thesis Proposal
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Students submit written proposals for thesis according to stated deadlines.
Staff
No textbook information available

9.95 Research Topics in Neuroscience
______

Undergrad (IAP) Can be repeated for credit
Prereq: None
Units: 1-0-0 [P/D/F]
______
Lecture series that highlights faculty research in various fields of neuroscience. Each of the six lectures focuses on a specific area of brain research, delineating issues, methods, and findings pertinent to the topic. Exam administered during seventh and final class session. Pre-register on WebSIS; must attend first class.
P. H. Schiller

9.97 Introduction to Neuroanatomy
______

Undergrad (IAP)
Prereq: None
Units: 1-0-0 [P/D/F]
______
Intensive introduction to neuroanatomy that consists of lectures, demonstrations, and interactive laboratories, including a brain dissection. No prior knowledge of neuroanatomy required, although general knowledge of brain structures is helpful. Pre-register on WebSIS; must attend first class. Limited to 100.
R. Ellis-Behnke

9.S51 Special Subject in Brain and Cognitive Sciences
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: 9.00 and any other two subjects in Brain and Cognitive Sciences
Units arranged
______
Undergraduate study in brain and cognitive sciences; covers material not offered in regular curriculum.
Consult Staff

9.S52 Special Subject in Brain and Cognitive Sciences
______

Undergrad (Spring) Can be repeated for credit
Prereq: 9.00 and any other two subjects in Brain and Cognitive Sciences
Units arranged
______
Undergraduate study in brain and cognitive sciences; covers material not offered in regular curriculum.
Consult Staff

9.S911-9.S917 Special Subject in Brain and Cognitive Sciences
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
9.S911: Meets 9/22 to 9/29. Lecture: R EVE (5-7 PM) (46-3310)
Subject Cancelled 9.S912 Cancelled
9.S915: Lecture: TR3-4.30 (46-5193)
9.S916: Lecture: R10-11.30 (46-5193)
9.S917: TBA.
______
Advanced graduate study in brain and cognitive sciences; covers material not offered in regular curriculum. 9.S911 is graded P/D/F.
J. Di Carlo
9.S911: No textbook information available
9.S915: No textbook information available
9.S916: No textbook information available
9.S917: No textbook information available

9.S92 Special Subject in Brain and Cognitive Sciences
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: 9.00
Units arranged
TBA.
______
Undergraduate study in brain and cognitive sciences; covers material not offered in regular curriculum.
Consult Staff
No textbook information available

9.S93-9.S99 Special Subject in Brain and Cognitive Sciences
______

Undergrad (IAP)
Prereq: None
Units arranged [P/D/F]
______
For undergraduate study in brain and cognitive sciences during Independent Activities Period; covers material not offered in regular curriculum. See IAP Guide for details.
Staff

9.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of a Ph.D. thesis; to be arranged by the student and an appropriate MIT faculty member.
Staff
Textbooks arranged individually

9.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually

9.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Individual participation in an ongoing research project.
Consult Staff
Textbooks arranged individually


left arrow|9.00-9.499|9.50-9.999 plus Thesis, UROP|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 10: Chemical Engineering
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Course 10: Chemical Engineering
Fall 2016


10.00 Molecule Builders
______

Undergrad (Spring)
Prereq: Chemistry (GIR), Physics I (GIR)
Units: 1-6-2
______
Project-based introduction to the applications of engineering design at the molecular level. Working in teams, students complete an open-ended design project that focuses on a topic such as reactor or biomolecular engineering, chemical process design, materials and polymers, or energy. Provides students practical exposure to the field of chemical engineering as well as potential opportunities to continue their project designs in national/international competitions. Limited to 36; preference to first year students.
B. D. Olsen

10.01 Ethics for Engineers
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.082,2.900,6.904,10.01,22.014)
Prereq: None
Units: 2-0-4
Lecture: M3-5 (66-144, 36-153) or T3-5 (37-212) or T EVE (7.30-9.30 PM) (66-144) or W3-5 (36-153)
______
Integrates classical readings that provide an overview of ethics with a survey of case studies that focus on ethical problems arising in the practice of engineering. Readings taken from a variety of sources, such as Aristotle, Machiavelli, Bacon, Hobbes, Locke, the Founding Fathers, and the Bible. Case studies include written analyses and films that address engineering disasters, biotechnology, court cases, ethical codes, and the ultimate scope and aims of engineering.
D. Doneson, B. L. Trout
No textbook information available

10.02 Foundations of Entrepreneurship for Engineers
______

Undergrad (Spring)
Prereq: None
Units: 3-0-9
______
Studies economic and leadership foundations of entrepreneurship as they relate to engineering. Case studies illustrate major impacts of engineering on the world and examine the leaders responsible for such impacts. Authors include Franklin, Keynes, Leonardo, Lincoln, Locke, Machiavelli, Marx, Schmidt, Schumpeter, Smith, Thiel, and Tocqueville. Discusses topics such as the difference between an entrepreneur and a manager, the entrepreneur as founder, and characteristics of principled entrepreneurship.
D. Doneson, B. L. Trout

10.03[J] Advances in Biomanufacturing
______

Undergrad (Fall, Spring); second half of term
(Same subject as 7.458[J])
(Subject meets with7.548[J],10.53[J])
Prereq: None
Units: 1-0-2 [P/D/F]
Begins Oct 24. Lecture: TR11 (66-148)
______
Seminar examines how biopharmaceuticals, an increasingly important class of pharmaceuticals, are manufactured. Topics range from fundamental bioprocesses to new technologies to the economics of biomanufacturing. Also covers the impact of globalization on regulation and quality approaches as well as supply chain integrity. Students taking graduate version complete additional assignments.
J. C. Love, A. Sinskey, S. Springs
No textbook information available

10.04[J] A Philosophical History of Energy
______

Undergrad (Spring) HASS Humanities Communication Intensive HASS
(Same subject as24.114[J])
Prereq: None
Units: 3-0-9
______
Philosophic and historical approach to conceptions of energy through the 19th century. Relation of long standing scientific and philosophic problems in the field of energy to 21st-century debates. Topics include the development of thermodynamics and kinetic theories, the foundation of the scientific project, the classical view of energy, and the harnessing of nature. Authors include Bacon, Boltzmann, Carnot, Compte, Descartes, Gibbs, Plato, Aristotle, Leibniz, Kant, Hegel, Mill, Peirce, Whitehead, and Maxwell. Key texts and controversies form topics of weekly writing assignments and term papers.
B. L. Trout, A. Schulman

10.10 Introduction to Chemical Engineering
______

Undergrad (Fall, Spring)
Prereq: Chemistry (GIR), Physics I (GIR), Calculus I (GIR)
Units: 4-0-8
Lecture: MWF2 (56-114) Recitation: T12 (66-168) +final
______
The diverse applications of chemical engineering are explored through example problems. Solutions require application of fundamental concepts of mass and energy conservation to batch and continuous systems, involving chemical and biological processes. Computer skills and the elements of engineering design are taught in the context of these example problems. The objective is to acquaint the student with the field of chemical engineering and to enable use of computer methods to solve chemical and biological engineering problems.
B. S. Johnston, K. L. J. Prather
Textbooks (Fall 2016)

10.213 Chemical and Biological Engineering Thermodynamics
______

Undergrad (Spring)
Prereq: 5.60, 10.10
Units: 4-0-8
______
Thermodynamics of multicomponent, multiphase chemical and biological systems. Applications of first, second, and third laws of thermodynamics to open and closed systems. Properties of mixtures, including colligative properties, chemical reaction equilibrium, and phase equilibrium; non-ideal solutions; power cycles; refrigeration; separation systems.
K. K. Gleason, H. D. Sikes

10.22 Molecular Engineering
______

Undergrad (Spring)
Prereq: 5.60, 10.213
Units: 3-0-9
______
Introduces molecular concepts in relation to engineering thermodynamics. Includes topics in statistical mechanics, molecular description of gases and liquids, property estimation, description of equilibrium and dynamic properties of fluids from molecular principles, and kinetics of activated processes. Also covers some basic aspects of molecular simulation and applications in systems of engineering interest.
G. C. Rutledge, P. S. Doyle

10.25 Industrial Chemistry and Chemical Process Pathways
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: Chemistry (GIR), 10.213, 10.37
Units: 3-0-6
______
Chemical and engineering principles involved in creation and operation of viable industrial processes. Topics: analysis of process chemistry by p-pathways (i.e., radical, ionic, and pericyclic reactions of organic syntheses) and d-pathways (i.e., catalysis by transition-metal complexes). Use of reaction mechanisms for inference of co-product formation, kinetics, and equilibria: process synthesis logic related to reaction selectivity, recycle, separations. Illustrations drawn from current and contemplated commercial practice.
P. S. Virk

10.26 Chemical Engineering Projects Laboratory
______

Undergrad (Spring)
(Subject meets with10.27,10.29)
Prereq: 2.671, 3.014, 5.310, 7.02, 12.335, or 1.106 and 1.107; 10.302; or permission of instructor
Units: 3-8-4
URL: http://web.mit.edu/10.26/www/
______
Projects in applied chemical engineering research. Students work in teams on one project for the term. Projects often suggested by local industry. Includes training in research planning and project management, execution of experimental work, data analysis, oral presentation skills and individual report writing, and team-building.
C. K. Colton, B. S. Johnston, B. D. Burrell, G. C. Rutledge

10.27 Energy Engineering Projects Laboratory
______

Undergrad (Spring)
(Subject meets with10.26,10.29)
Prereq: 2.671, 3.014, 5.310, 7.02, 12.335, or 1.106 and 1.107; 10.302; or permission of instructor
Units: 3-8-4
______
Projects in applied energy engineering research. Students work in teams on one project for the term. Projects often suggested by local industry. Includes training in research planning and project management, execution of experimental work, data analysis, oral presentation skills and technical report writing, and team-building. Projects consider social science issues in addition to technical issues. Intended for students with diverse technical backgrounds. Preference to Energy Studies minors.
C. K. Colton, M. S. Strano, J. F. Hamel, W. A. Tisdale, G. Stephanopoulos

10.28 Chemical-Biological Engineering Laboratory
______

Undergrad (Fall)
Prereq: 5.310 or 10.702; 7.05 or 5.07; or permission of instructor
Units: 2-8-5
URL: http://web.mit.edu/10.28/www
Lecture: M3-5 (66-156) Lab: WF1-5 (66-0042)
______
Introduces the complete design of the bioprocess: from vector selection to production, separation, and characterization of recombinant products. Utilize concepts from many fields, such as, chemical and electrical engineering, and biology. Student teams work through parallel modules spanning microbial fermentation and animal cell culture. With the bioreactor at the core of the experiments, students study cell metabolism and biological pathways, kinetics of cell growth and product formation, oxygen mass transport, scale-up and techniques for the design of process control loops. Introduces novel bioreactors and powerful analytical instrumentation. Downstream processing and recombinant product purification also included. Enrollment limited.
J.-F. Hamel
No textbook information available

10.29 Biological Engineering Projects Laboratory
______

Undergrad (Spring)
(Subject meets with10.26,10.27)
Prereq: 2.671, 3.014, 5.310, 7.02, 12.335, or 1.106 and 1.107; 10.302; or permission of instructor
Units: 3-8-4
______
Projects in applied biological engineering research. Students work in teams on one project for the term. Projects often suggested by local industry. Includes training in research planning and project management, execution of experimental work, data analysis, oral presentation skills and report writing, and team-building.
C. K. Colton, J. F. Hamel, D. G. Anderson

10.291[J] Introduction to Sustainable Energy
______

Undergrad (Fall)
(Same subject as2.650[J],22.081[J])
(Subject meets with1.818[J],2.65[J],10.391[J],11.371[J],22.811[J])
Prereq: Permission of instructor
Units: 3-1-8
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various renewable and conventional energy production technologies, energy end-use practices and alternatives, and consumption practices in different countries. Investigates their attributes within a quantitative analytical framework for evaluation of energy technology system proposals. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments. Limited to juniors and seniors.
M. W. Golay
Textbooks (Fall 2016)

10.301 Fluid Mechanics
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: 18.03, 10.10
Units: 4-0-8
______
Introduces the mechanical principles governing fluid flow. Stress in a fluid. Conservation of mass and momentum, using differential and integral balances. Elementary constitutive equations. Hydrostatics. Exact solutions of the Navier-Stokes equations. Approximate solutions using control volume analysis. Mechanical energy balances and Bernoulli's equation. Dimensional analysis and dynamic similarity. Introduces boundary-layer theory and turbulence.
P. S. Doyle, F. R. Brushett

10.302 Transport Processes
______

Undergrad (Fall)
Prereq: 5.60, 10.301, 10.213; or permission of instructor
Units: 4-0-8
Lecture: MWF12 (66-110) Recitation: T11 (66-144) or T12 (66-144) +final
______
Principles of heat and mass transfer. Steady and transient conduction and diffusion. Radiative heat transfer. Convective transport of heat and mass in both laminar and turbulent flows. Emphasis on the development of a physical understanding of the underlying phenomena and upon the ability to solve real heat and mass transfer problems of engineering significance.
W. A. Tisdale, K. Chung
Textbooks (Fall 2016)

10.31 Nanoscale Energy Transport Processes
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with10.51)
Prereq: 10.302 or 2.51; 3.024, 5.61, or 6.007; or permission of instructor
Units: 3-0-9
______
Explores the impact of nanoscale phenomena on macroscale transport of energy-carrying molecules, phonons, electrons, and excitons. Studies the effect of structural and energetic disorder, wave-like vs. particle-like transport, quantum and classical size effects, and quantum coherence. Emphasizes quantitative analysis, including the Boltzmann transport equation, Einstein relation, Wiedemann-Franz law, and Marcus electron transfer theory. Also addresses percolation theory and the connection to energy conversion technologies, such as solar cells, thermoelectrics, and LEDs. Students taking graduate version complete additional assignments.
W. A. Tisdale

10.32 Separation Processes
______

Undergrad (Spring)
Prereq: 10.213, 10.302
Units: 2-0-4
______
General principles of separation by equilibrium and rate processes. Staged cascades. Applications to distillation, absorption, adsorption, and membrane processes. Use of material balances, phase equilibria, and diffusion to understand and design separation processes.
T. A. Hatton

10.333 Introduction to Modeling and Simulation
______

Undergrad (Spring) Rest Elec in Sci & Tech
Engineering School-Wide Elective Subject.
(Offered under:1.021,3.021,10.333,22.00)
Prereq: 18.03, 3.016, or permission of instructor
Units: 4-0-8
______
Basic concepts of computer modeling and simulation in science and engineering. Uses techniques and software for simulation, data analysis and visualization. Continuum, mesoscale, atomistic and quantum methods used to study fundamental and applied problems in physics, chemistry, materials science, mechanics, engineering, and biology. Examples drawn from the disciplines above are used to understand or characterize complex structures and materials, and complement experimental observations.
M. Buehler, R. Taylor

10.34 Numerical Methods Applied to Chemical Engineering
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
URL: http://web.mit.edu/10.34/www/
Lecture: MWF11 (66-110) +final
______
Numerical methods for solving problems arising in heat and mass transfer, fluid mechanics, chemical reaction engineering, and molecular simulation. Topics: numerical linear algebra, solution of nonlinear algebraic equations and ordinary differential equations, solution of partial differential equations (e.g. Navier-Stokes), numerical methods in molecular simulation (dynamics, geometry optimization). All methods are presented within the context of chemical engineering problems. Familiarity with structured programming is assumed.
W. H. Green, J. W. Swan
Textbooks (Fall 2016)

10.345 Fundamentals of Metabolic and Biochemical Engineering: Applications to Biomanufacturing
(New)
______

Undergrad (Spring)
(Subject meets with10.545)
Prereq: 5.07, 7.05, or permission of instructor
Units: 3-0-9
______
Examines the fundamentals of cell and metabolic engineering for biocatalyst design and optimization, as well as biochemical engineering principles for bioreactor design and operation, and downstream processing. Presents applications of microbial processes for production of commodity and specialty chemicals and biofuels in addition to mammalian cell cultures for production of biopharmaceuticals. Students taking graduate version complete additional assignments.
Gr. Stephanopoulos

10.37 Chemical Kinetics and Reactor Design
______

Undergrad (Spring)
Prereq: 5.60, 10.301
Units: 3-0-6
URL: http://web.mit.edu/10.37/www/
______
Applies the concepts of reaction rate, stoichiometry and equilibrium to the analysis of chemical and biological reacting systems. Derivation of rate expressions from reaction mechanisms and equilibrium or steady state assumptions. Design of chemical and biochemical reactors via synthesis of chemical kinetics, transport phenomena, and mass and energy balances. Topics: chemical/biochemical pathways; enzymatic, pathway and cell growth kinetics; batch, plug flow and well-stirred reactors for chemical reactions and cultivations of microorganisms and mammalian cells; heterogeneous and enzymatic catalysis; heat and mass transport in reactors, including diffusion to and within catalyst particles and cells or immoblized enzymes.
Gr. Stephanopoulos, Y. Roman

10.390[J] Fundamentals of Advanced Energy Conversion
______

Undergrad (Spring)
(Same subject as2.60[J])
(Subject meets with2.62[J],10.392[J],22.40[J])
Prereq: 2.006, or 2.051 and 2.06, or permission of instructor
Units: 4-0-8
______
Fundamentals of thermodynamics, chemistry, and transport applied to energy systems. Analysis of energy conversion and storage in thermal, mechanical, chemical, and electrochemical processes in power and transportation systems, with emphasis on efficiency, performance, and environmental impact. Applications to fuel reforming and alternative fuels, hydrogen, fuel cells and batteries, combustion, catalysis, combined and hybrid power cycles using fossil, nuclear and renewable resources. CO2 separation and capture. Biomass energy. Students taking graduate version complete additional assignments.
A. F. Ghoniem, W. Green

10.391[J] Sustainable Energy
______

Graduate (Fall)
(Same subject as1.818[J],2.65[J],11.371[J],22.811[J])
(Subject meets with2.650[J],10.291[J],22.081[J])
Prereq: Permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/10.391J/www/
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various energy technologies in each fuel cycle stage for fossil (oil, gas, synthetic), nuclear (fission and fusion) and renewable (solar, biomass, wind, hydro, and geothermal) energy types, along with storage, transmission, and conservation issues. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments.
M. W. Golay
Textbooks (Fall 2016)

10.392[J] Fundamentals of Advanced Energy Conversion
______

Graduate (Spring)
(Same subject as2.62[J],22.40[J])
(Subject meets with2.60[J],10.390[J])
Prereq: 2.006, or 2.051 and 2.06, or permission of instructor
Units: 4-0-8
______
Fundamentals of thermodynamics, chemistry, and transport applied to energy systems. Analysis of energy conversion and storage in thermal, mechanical, chemical, and electrochemical processes in power and transportation systems, with emphasis on efficiency, performance and environmental impact. Applications to fuel reforming and alternative fuels, hydrogen, fuel cells and batteries, combustion, catalysis, combined and hybrid power cycles using fossil, nuclear and renewable resources. CO2 separation and capture. Biomass energy. Meets with 2.60 when offered concurrently; students taking the graduate version complete additional assignments.
A. F. Ghoniem, W. Green

10.40 Chemical Engineering Thermodynamics
______

Graduate (Fall)
Prereq: 10.213
Units: 4-0-8
Lecture: TR9-11 (66-110) +final
______
Basic postulates of classical thermodynamics. Application to transient open and closed systems. Criteria of stability and equilibria. Constitutive property models of pure materials and mixtures emphasizing molecular-level effects using the formalism of statistical mechanics. Phase and chemical equilibria of multicomponent systems. Applications emphasized through extensive problem work relating to practical cases.
D. Blankschtein
Textbooks (Fall 2016)

10.407[J] Funding Strategies for Startups
______

Graduate (Spring); second half of term
(Same subject as2.916[J])
Prereq: None
Units: 2-0-4
______
Introduction to the substance and process of funding technology startups. Topics include a comparative analysis of various sources of capital; templates to identify the optimal investor; legal frameworks, US and offshore, of the investment process and its related jargon; an introduction to understanding venture capital as a business; and market practice and standards for term sheet negotiation. Emphasizes strategy as well as tactics necessary to negotiate and build effective, long-term relationships with investors, particularly venture capital firms (VCs).
S. Loessberg, D. P. Hart

10.424 Pharmaceutical Engineering
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with10.524)
Prereq: 10.213
Units: 3-0-6
______
Presents engineering principles and unit operations involved in the manufacture of small molecules pharmaceuticals, from the isolation of purified active pharmaceutical ingredients (API) to the final production of drug product. Regulatory issues include quality by design and process analytical technologies of unit operations, such as crystallization, filtration, drying, milling, blending, granulation, tableting and coating. Also covers principles of formulation for solid dosage forms and parenteral drugs. Students taking graduate version complete additional assignments. Limited to 50.
A. S. Myerson

10.426 Electrochemical Energy Systems
______

Undergrad (Spring)
(Subject meets with10.626)
Prereq: 10.302 or permission of instructor
Units: 3-0-9
______
Introduces principles and mathematical models of electrochemical energy conversion and storage. Studies equivalent circuits, thermodynamics, reaction kinetics, transport phenomena, electrostatics, porous media, and phase transformations. Includes applications to batteries, fuel cells, supercapacitors, and electrokinetics. Students taking graduate version complete additional assignments.
M. Z. Bazant

10.43 Introduction to Interfacial Phenomena
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 10.213 or introductory subject in thermodynamics or physical chemistry
Units: 3-0-6
______
Introduces fundamental and applied aspects of interfacial systems. Theory of capillarity. Experimental determination of surface and interfacial tensions. Thermodynamics of interfaces. The Gibbs adsorption equation. Charged interfaces. Surfactant adsorption at interfaces. Insoluble monolayers. Curvature effects on the equilibrium state of fluids. Nucleation and growth. Fundamentals of wetting and contact angle. Adhesion, cohesion, and spreading. Wetting of textured surfaces. Super-hydrophilic and super-hydrophobic surfaces. Self-cleaning surfaces.
D. Blankschtein

10.437[J] Quantum Chemical Simulation
______

Undergrad (Fall)
(Same subject as5.697[J])
(Subject meets with5.698[J],10.637[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (14-0637)
______
Addresses both the theory and application of first-principles computer simulations methods (i.e., quantum, chemical, or electronic structure), including Hartree-Fock theory, density functional theory, and correlated wavefunction methods. Covers enhanced sampling, ab initio molecular dynamics, and transition-path-finding approaches as well as errors and accuracy in total and free energies. Discusses applications such as the study and prediction of properties of chemical systems, including heterogeneous, molecular, and biological catalysts (enzymes), and physical properties of materials. Students taking graduate version complete additional assignments.
H. J. Kulik
Textbooks (Fall 2016)

10.441[J] Molecular and Engineering Aspects of Biotechnology
______

Undergrad (Spring)
(Same subject as7.37[J],20.361[J])
Prereq: 2.005, 3.012, 5.60, or 20.110; 7.06; or permission of instructor
Units: 4-0-8
Credit cannot also be received for7.371
URL: http://web.mit.edu/7.37j/
______
Covers biological and bioengineering principles underlying the development and therapeutic use of recombinant proteins and stem cells; glycoengineering of recombinant proteins; normal and pathological signaling by growth factors and their receptors; receptor trafficking; monoclonal antibodies as therapeutics; protein pharmacology and delivery; stem cell-derived tissues as therapeutics; RNA therapeutics; combinatorial protein engineering; and new antitumor drugs.
H. Lodish, L. Griffith

10.443 Future Medicine: Drug Delivery, Therapeutics, and Diagnostics
______

Undergrad (Spring)
(Subject meets with10.643[J],HST.526[J])
Prereq: 5.12 or permission of instructor
Units: 3-0-6
______
Aims to describe the direction and future of medical technology. Introduces pharmaceutics, pharmacology, and conventional medical devices, then transitions to drug delivery systems, mechanical/electric-based and biological/cell-based therapies, and sensors. Covers nano- and micro drug delivery systems, including polymer-drug conjugates, protein therapeutics, liposomes and polymer nanoparticles, viral and non-viral genetic therapy, and tissue engineering. Previous coursework in cell biology and organic chemistry recommended. Students taking graduate version complete additional assignments. Limited to 40.
D. G. Anderson

10.450 Process Dynamics, Operations, and Control
______

Undergrad (Spring)
Prereq: 10.302, 18.03
Units: 3-0-6
______
Introduction to dynamic processes and the engineering tasks of process operations and control. Subject covers modeling the static and dynamic behavior of processes; control strategies; design of feedback, feedforward, and other control structures; model-based control; applications to process equipment.
B. S. Johnston

10.466 Structure of Soft Matter
______

Not offered academic year 2017-2018Undergrad (Fall)
(Subject meets with10.566)
Prereq: 5.60
Units: 3-0-6
Lecture: MW9.30-11
______
Provides an introduction to the basic thermodynamic language used for describing the structure of materials, followed by a survey of the scattering, microscopy and spectroscopic techniques for structure and morphology characterization. Applies these concepts to a series of case studies illustrating the diverse structures formed in soft materials and the common length, time and energy scales that unify this field. For students interested in studying polymer science, colloid science, nanotechnology, biomaterials, and liquid crystals. Students taking graduate version complete additional assignments.
B. D. Olsen
No textbook information available

10.467 Polymer Science Laboratory
______

Undergrad (Fall)
Prereq: 5.12, 5.310
Units: 2-7-6
Lecture: MT1 (66-144) Lab: T2-5,R1-5 (E18-676)
______
Experiments broadly aimed at acquainting students with the range of properties of polymers, methods of synthesis, and physical chemistry. Examples: solution polymerization of acrylamide, bead polymerization of divinylbenzene, interfacial polymerization of nylon 6,10. Evaluation of networks by tensile and swelling experiments. Rheology of polymer solutions and suspensions. Physical properties of natural and silicone rubber. Preference to Course 10 seniors and juniors.
J. C. Love, D. G. Anderson
No textbook information available

10.489 Concepts in Modern Heterogeneous Catalysis
______

Undergrad (Spring)
Not offered regularly; consult department
(Subject meets with10.689)
Prereq: 10.37, 10.302
Units: 3-0-6
______
Explores topics in the design and implementation of heterogeneous catalysts for chemical transformations. Emphasizes use of catalysis for environmentally benign and sustainable chemical processes. Lectures address concepts in catalyst preparation, catalyst characterization, quantum chemical calculations, and microkinetic analysis of catalytic processes. Shows how experimental and theoretical approaches can illustrate important reactive intermediates and transition states involved in chemical reaction pathways, and uses that information to help identify possible new catalysts that may facilitate reactions of interest. Draws examples from current relevant topics in catalysis. Includes a group project in which students investigate a specific topic in greater depth. Students taking graduate version complete additional assignments.
Y. Roman

10.490 Integrated Chemical Engineering I
______

Undergrad (Fall); first half of term
Prereq: 10.37
Units: 3-0-5
Ends Nov 10. Lecture: MTRF10 (66-168) or MTRF11 (66-168)
______
Textbooks (Fall 2016)

10.491 Integrated Chemical Engineering II
______

Undergrad (Spring); first half of term
Prereq: 10.490
Units: 3-0-5
______
Presents and solves chemical engineering problems in an industrial context, with applications varying by term. Emphasis on the integration of fundamental concepts with approaches of process design. Emphasis on problems that demand synthesis, economic analysis, and process design.
P. I. Barton, B. S. Johnston

10.492 Integrated Chemical Engineering Topics I
______

Undergrad (Fall); second half of term
Prereq: 10.301 and permission of instructor
Units: 2-0-2
URL: http://web.mit.edu/cheme/
Begins Nov 14. Lecture: MTRF10 (66-168) or MTRF11 (66-168) or MTRF10 (66-160) or MTRF11 (66-160)
______
Chemical engineering problems presented and analyzed in an industrial context. Emphasizes the integration of fundamentals with material property estimation, process control, product development, and computer simulation. Integration of societal issues, such as engineering ethics, environmental and safety considerations, and impact of technology on society are addressed in the context of case studies. 10.37 and 10.302 required for certain topic modules. See departmental website for individual ICE-T module descriptions.
K. F. Jensen, Geo. Stephanopoulos
No required or recommended textbooks

10.493 Integrated Chemical Engineering Topics II
______

Undergrad (IAP)
Prereq: 10.301 and permission of instructor
Units: 2-0-2
URL: http://web.mit.edu/cheme/
______

10.494 Integrated Chemical Engineering Topics III
______

Undergrad (Spring)
Prereq: 10.301 and permission of instructor
Units: 2-0-2
URL: http://web.mit.edu/cheme/
______
Chemical engineering problems presented and analyzed in an industrial context. Emphasizes the integration of fundamentals with material property estimation, process control, product development, and computer simulation. Integration of societal issues, such as engineering ethics, environmental and safety considerations, and impact of technology on society are addressed in the context of case studies. 10.37 and 10.302 required for certain topic modules. See departmental website for individual ICE-T module descriptions.
K. F. Jensen, R. C. Armstrong

10.495 Molecular Design and Bioprocess Development of Immunotherapies
______

Undergrad (Spring)
(Subject meets with10.595)
Prereq: 7.06 or permission of instructor
Units: 3-0-6
______
Examines challenges and opportunities for applying chemical engineering principles to address the growing global burden of infectious disease, including drug-resistant strains and neglected pathogens. Topics include a historical overview of vaccines and immunotherapies, the molecular design considerations for new immunotherapies and adjuvants, the economic challenges for process development and manufacturing of immunotherapies, and new technologies for designing and assessing therapies. Case studies to cover topics for specific diseases. Students taking graduate version complete additional assignments.
J. C. Love

10.50 Analysis of Transport Phenomena
______

Graduate (Fall)
Prereq: 10.301, 10.302
Units: 4-0-8
Lecture: MWF1-2.30 (66-110) +final
______
Unified treatment of heat transfer, mass transfer, and fluid mechanics, emphasizing scaling concepts in formulating models and analytical methods for obtaining solutions. Topics include conduction and diffusion, laminar flow regimes, convective heat and mass transfer, and simultaneous heat and mass transfer with chemical reaction or phase change.
W. M. Deen, M. Z. Bazant
Textbooks (Fall 2016)

10.51 Nanoscale Energy Transport Processes
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with10.31)
Prereq: 10.302 or 2.51; 3.024, 5.61, or 6.007; or permission of instructor
Units: 3-0-9
______
Explores the impact of nanoscale phenomena on macroscale transport of energy-carrying molecules, phonons, electrons, and excitons. Studies the effect of structural and energetic disorder, wave-like vs. particle-like transport, quantum and classical size effects, and quantum coherence. Emphasizes quantitative analysis, including the Boltzmann transport equation, Einstein relation, Wiedemann-Franz law, and Marcus electron transfer theory. Also addresses percolation theory and the connection to energy conversion technologies, such as solar cells, thermoelectrics, and LEDs. Students taking graduate version complete additional assignments.
W. A. Tisdale

10.52 Mechanics of Fluids
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 10.50
Units: 3-0-6
______
Advanced subject in fluid and continuum mechanics. Content includes kinematics, macroscopic balances for linear and angular momentum, the stress tensor, creeping flows and the lubrication approximation, the boundary layer approximation, linear stability theory, and some simple turbulent flows.
Staff

10.524 Pharmaceutical Engineering
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with10.424)
Prereq: None
Units: 3-0-6
______
Presents engineering principles and unit operations involved in the manufacture of small molecules pharmaceuticals, from the isolation of purified active pharmaceutical ingredients (API) to the final production of drug product. Regulatory issues include quality by design and process analytical technologies of unit operations, such as crystallization, filtration, drying, milling, blending, granulation, tableting and coating. Also covers principles of formulation for solid dosage forms and parenteral drugs. Students taking graduate version complete additional assignments. Limited to 50.
A. S. Myerson

10.53[J] Advances in Biomanufacturing
______

Graduate (Fall, Spring); second half of term
(Same subject as7.548[J])
(Subject meets with 7.458[J],10.03[J])
Prereq: None
Units: 1-0-2
Begins Oct 24. Lecture: TR11 (66-148)
______
Seminar examines how biopharmaceuticals, an increasingly important class of pharmaceuticals, are manufactured. Topics range from fundamental bioprocesses to new technologies to the economics of biomanufacturing. Also covers the impact of globalization on regulation and quality approaches as well as supply chain integrity. Students taking graduate version complete additional assignments.
J. C. Love, A. Sinskey, S. Springs
No textbook information available

10.531[J] Macromolecular Hydrodynamics
______

Graduate (Spring)
(Same subject as2.341[J])
Prereq: 2.25, 10.301, or permission of instructor
Units: 3-0-6
______
Physical phenomena in polymeric liquids undergoing deformation and flow. Kinematics and material functions for complex fluids; techniques of viscometry, rheometry; and linear viscoelastic measurements for polymeric fluids. Generalized Newtonian fluids. Continuum mechnanics, frame invariance, and convected derivatives for finite strain viscoelasticity. Differential and integral constitutive equations for viscoelastic fluids. Analytical solutions to isothermal and non-isothermal flow problems; the roles of non-Newtonian viscosity, linear viscoelasticity, normal stresses, elastic recoil, stress relaxation in processing flows. Introduction to molecular theories for dynamics of polymeric fluids. (Extensive class project and presentation required instead of a final exam).
R. C. Armstrong, G. H. McKinley

10.536[J] Thermal Hydraulics in Power Technology
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as 2.59[J],22.313[J])
Prereq: 2.006, 10.302, 22.312, or permission of instructor
Units: 3-2-7
______
Emphasis on thermo-fluid dynamic phenomena and analysis methods for conventional and nuclear power stations. Kinematics and dynamics of two-phase flows. Steam separation. Boiling, instabilities, and critical conditions. Single-channel transient analysis. Multiple channels connected at plena. Loop analysis including single and two-phase natural circulation. Subchannel analysis.
E. Baglietto

10.537[J] Molecular, Cellular, and Tissue Biomechanics
______

Graduate (Fall)
(Same subject as2.798[J],3.971[J],6.524[J],20.410[J])
Prereq: Biology (GIR); 2.002, 2.006, 6.013, 10.301, or 10.302
Units: 3-0-9
Lecture: TR10.30-12 (2-143)
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, K. J. Van Vliet
No textbook information available

10.538[J] Biomolecular Kinetics and Cellular Dynamics
______

Graduate (Fall)
(Same subject as20.420[J])
Prereq: 7.06, 18.03
Units: 3-0-9
Lecture: TR9.30-11 +final
______
Fundamental analysis of biological rate processes using approaches from biomolecular reaction kinetics and dynamical systems engineering. Topics include binding and hybridization interactions, enzyme reactions, metabolic cycles, gene regulation, receptor/ligand trafficking systems, intra- and intercellular signaling, and cell population dynamics.
A. Jasanoff, E. Fraenkel
No textbook information available

10.539[J] Fields, Forces, and Flows in Biological Systems
______

Graduate (Fall)
(Same subject as2.795[J],6.561[J],20.430[J])
Prereq: 6.013, 2.005, 10.302, or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (32-124)
______
Molecular diffusion, diffusion-reaction, conduction, convection in biological systems; fields in heterogeneous media; electrical double layers; Maxwell stress tensor, electrical forces in physiological systems. Fluid and solid continua: equations of motion useful for porous, hydrated biological tissues. Case studies of membrane transport, electrode interfaces, electrical, mechanical, and chemical transduction in tissues, convective-diffusion/reaction, electrophoretic, electroosmotic flows in tissues/MEMs, and ECG. Electromechanical and physicochemical interactions in cells and biomaterials; musculoskeletal, cardiovascular, and other biological and clinical examples.
M. Bathe, A. J. Grodzinsky
Textbooks (Fall 2016)

10.540 Intracellular Dynamics
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 18.03, 7.06, 10.302, or permission of instructor
Units: 3-0-9
______
Covers current models and descriptions of the internal cell dynamics of macromolecules due to reaction and transport. Two major areas will be explored: the process of gene expression, including protein-DNA interactions, chromatin dynamics, and the stochastic nature of gene expression; and cell signaling systems, especially those that lead to or rely on intracellular protein gradients. This class is intended for graduate students or advanced undergraduates with some background in cell biology, transport, and kinetics. An introductory class in probability is recommended.
N. Maheshri

10.542 Biochemical Engineering
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
______
Interaction of chemical engineering, biochemistry, and microbiology. Mathematical representations of microbial systems. Kinetics of growth, death, and metabolism. Continuous fermentation, agitation, mass transfer, and scale-up in fermentation systems, enzyme technology.
K. J. Prather

10.544 Metabolic and Cell Engineering
______

Not offered academic year 2016-2017Graduate (Fall, Spring)
Prereq: 7.05, 10.302, 18.03
Units: 3-0-9
______
Presentation of a framework for quantitative understanding of cell functions as integrated molecular systems. Analysis of cell-level processes in terms of underlying molecular mechanisms based on thermodynamics, kinetics, mechanics, and transport principles, emphasizing an engineering, problem-oriented perspective. Objective is to rationalize target selection for genetic engineering and evaluate the physiology of recombinant cells. Topics include cell metabolism and energy production, transport across cell compartment barriers, protein synthesis and secretion, regulation of gene expression, transduction of signals from extracellular environment, cell proliferation, cell adhesion and migration.
Gr. Stephanopoulos

10.545 Fundamentals of Metabolic and Biochemical Engineering: Applications to Biomanufacturing
(New)
______

Graduate (Spring)
(Subject meets with10.345)
Prereq: 5.07, 7.05, or permission of instructor
Units: 3-0-9
______
Examines the fundamentals of cell and metabolic engineering for biocatalyst design and optimization, as well as biochemical engineering principles for bioreactor design and operation, and downstream processing. Presents applications of microbial processes for production of commodity and specialty chemicals and biofuels in addition to mammalian cell cultures for production of biopharmaceuticals. Students taking graduate version complete additional assignments.
Gr. Stephanopoulos

10.546[J] Statistical Thermodynamics
______

Graduate (Fall)
(Same subject as5.70[J])
Prereq: 5.60 or permission of instructor
Units: 3-0-9
Lecture: MW8.30-10 (4-231)
______
Develops classical equilibrium statistical mechanical concepts for application to chemical physics problems. Basic concepts of ensemble theory formulated on the basis of thermodynamic fluctuations. Examples of applications include Ising models, lattice models of binding, ionic and non-ionic solutions, liquid theory, polymer and protein conformations, phase transition, and pattern formation. Introduces computational techniques with examples of liquid and polymer simulations.
A. Willard, B. Zhang
Textbooks (Fall 2016)

10.547[J] Principles and Practice of Drug Development
______

Graduate (Fall)
(Same subject as7.547[J],15.136[J],HST.920[J],IDS.620[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://hst-hu-mit.mit.edu/courses/HST920
Lecture: W EVE (3-6 PM) (1-190)
______
Description and critical assessment of the major issues and stages of developing a pharmaceutical or biopharmaceutical. Drug discovery, preclinical development, clinical investigation, manufacturing and regulatory issues considered for small and large molecules. Economic and financial considerations of the drug development process. Multidisciplinary perspective from faculty in clinical; life; and management sciences; as well as industry guests.
T. J. Allen, C. L. Cooney, S. N. Finkelstein, A. J. Sinskey, G. K. Raju
No textbook information available

10.548[J] Tumor Pathophysiology and Transport Phenomena: A Systems Biology Approach
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject asHST.525[J])
Prereq: 18.03; 10.301
Units: 2-0-4
______
Tumor pathophysiology plays a central role in the growth, invasion, metastasis and treatment of solid tumors. Principles of transport phenomena are applied to develop a systems level, quantitative understanding of angiogenesis, blood flow and microcirculation, metabolism and microenvironment, transport and binding of small and large molecules, movement of cancer and immune cells, metastatic process, and treatment response.
R. K. Jain

10.55 Colloid and Surfactant Science
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
______
Introduces fundamental and applied aspects of colloidal dispersions, where the typical particle size is less than a micrometer. Discusses the characterization and unique behavior of colloidal dispersions, including their large surface-to-volume ratio, tendency to sediment in gravitational and centrifugal fields, diffusion characteristics, and ability to generate osmotic pressure and establish Donnan equilibrium. Covers the fundamentals of attractive van der Waals forces and repulsive electrostatic forces. Presents an in-depth discussion of electrostatic and polymer-induced colloid stabilization, including the DLVO theory of colloid stability. Presents an introductory discussion of surfactant physical chemistry.
D. Blankschtein

10.551 Systems Engineering
______

Graduate (Spring)
Prereq: 10.213, 10.302, 10.37
Units: 3-0-6
URL: http://web.mit.edu/10.551/www/
______
Introduction to the elements of systems engineering. Special attention devoted to those tools that help students structure and solve complex problems. Illustrative examples drawn from a broad variety of chemical engineering topics, including product development and design, process development and design, experimental and theoretical analysis of physico-chemical process, analysis of process operations.
Geo. Stephanopoulos, R. D. Braatz

10.552 Advanced Systems Engineering
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: None
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Covers modern methods for dynamical systems analysis, state estimation, controller design, and related topics. Uses example applications to demonstrate Lyapunov and linear matrix inequality-based methods that explicitly address actuator constraints, nonlinearities, and model uncertainties. Limited to 30.
R. D. Braatz

10.555[J] Bioinformatics: Principles, Methods and Applications
______

Graduate (Spring)
(Same subject asHST.940[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Introduction to bioinformatics, the collection of principles and computational methods used to upgrade the information content of biological data generated by genome sequencing, proteomics, and cell-wide physiological measurements of gene expression and metabolic fluxes. Fundamentals from systems theory presented to define modeling philosophies and simulation methodologies for the integration of genomic and physiological data in the analysis of complex biological processes. Various computational methods address a broad spectrum of problems in functional genomics and cell physiology. Application of bioinformatics to metabolic engineering, drug design, and biotechnology also discussed.
Gr. Stephanopoulos, I. Rigoutsos

10.557 Mixed-integer and Nonconvex Optimization
______

Graduate (Spring)
Prereq: 10.34 or 15.053
Units: 3-0-9
______
Presents the theory and practice of deterministic algorithms for locating the global solution of NP-hard optimization problems. Recurring themes and methods are convex relaxations, branch-and-bound, cutting planes, outer approximation and primal-relaxed dual approaches. Emphasis is placed on the connections between methods. These methods will be applied and illustrated in the development of algorithms for mixed-integer linear programs, mixed-integer convex programs, nonconvex programs, mixed-integer nonconvex programs, and programs with ordinary differential equations embedded. The broad range of engineering applications for these optimization formulations will also be emphasized. Students will be assessed on homework and a term project for which examples from own research are encouraged.
P. I. Barton

10.56 Advanced Topics in Surfactant Science
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
______
Introduces fundamental advances and practical aspects of surfactant self-assembly in aqueous media. In-depth discussion of surfactant micellization, including statistical-thermodynamics of micellar solutions, models of micellar growth, molecular models for the free energy of micellization, and geometric packing theories. Presents an introductory examination of mixed micelle and vesicle formation, polymer-surfactant complexation, biomolecule-surfactant interactions, and micellar-assisted solubilization. Discusses molecular dynamics simulations of self-assembling systems. Covers recent advances in surfactant-induced dispersion and stabilization of colloidal particles (e.g., carbon nanotubes and graphene) in aqueous media. Examines surfactant applications in consumer products, environmental and biological separations, enhanced oil recovery using surfactant flooding, mitigation of skin irritation induced by surfactant-containing cosmetic products, and enhanced transdermal drug delivery using ultrasound and surfactants.
D. Blankschtein

10.560 Structure and Properties of Polymers
______

Graduate (Spring)
Prereq: 10.213 or permission of instructor
Units: 3-0-6
______
Review of polymer molecular structure and bulk morphology; survey of molecular and morphological influence on bulk physical properties including non-Newtonian flow, macromolecular diffusion, gas transport in polymers, electrical and optical properties, solid-state deformation, and toughness. Case studies for product design.
R. E. Cohen

10.562[J] Imaging and Sample Processing in Biology and Medicine
______

Graduate (Spring)
(Same subject asHST.562[J])
Prereq: Biology (GIR), 5.12; or permission of instructor
Units: 3-1-8
______
Discusses basic principles and concepts of bioimaging and sample processing. Topics include optical imaging modalities; optical/physical/chemical properties of a broad range of biological samples, including clinical tissues and sample handling/processing technologies; underlying engineering principles; and basic image analysis. Provides experience with optical microscopy and tissue processing technique (CLARITY). Limited to 15.
K. Chung

10.566 Structure of Soft Matter
______

Not offered academic year 2017-2018Graduate (Fall)
(Subject meets with10.466)
Prereq: 5.60
Units: 3-0-6
Lecture: MW9.30-11
______
Provides an introduction to the basic thermodynamic language used for describing the structure of materials, followed by a survey of the scattering, microscopy and spectroscopic techniques for structure and morphology characterization. Applies these concepts to a series of case studies illustrating the diverse structures formed in soft materials and the common length, time and energy scales that unify this field. For students interested in studying polymer science, colloid science, nanotechnology, biomaterials, and liquid crystals. Students taking graduate version complete additional assignments.
B. D. Olsen
No textbook information available

10.568 Physical Chemistry of Polymers
______

Graduate (Fall, Spring)
Prereq: 5.60, 10.213, or 10.40
Units: 3-0-6
Lecture: TR11-12.30 (66-154)
______
Chain macromolecules as random coils (unperturbed, expanded) and as other shapes. Statistical thermodynamics of interpenetrating random coiling polymers in solution with application to phase separations, swelling of networks, depression of melting point. The isolated chain molecule in dilute solutions analyzed for mass or size by static methods (osmometry, light scattering, neutron scattering) and by dynamic methods (intrinsic viscosity, size exclusion chromatography, sedimentation). Introduction to chain dynamics and to rubber elasticity.
R. E. Cohen
Textbooks (Fall 2016)

10.569 Synthesis of Polymers
______

Graduate (Spring)
Prereq: 5.12
Units: 3-0-6
______
Studies synthesis of polymeric materials, emphasizing interrelationships of chemical pathways, process conditions, and microarchitecture of molecules produced. Chemical pathways include traditional approaches such as anionic, radical condensation, and ring-opening polymerizations. New techniques, including stable free radicals and atom transfer free radicals, new catalytic approaches to well-defined architectures, and polymer functionalization in bulk and at surfaces. Process conditions include bulk, solution, emulsion, suspension, gas phase, and batch vs continuous fluidized bed. Microarchitecture includes tacticity, molecular-weight distribution, sequence distributions in copolymers, errors in chains such as branches, head-to-head addition, and peroxide incorporation.
P. T. Hammond, B. D. Olsen

10.571[J] Atmospheric Physics and Chemistry
______

Graduate (Spring)
(Same subject as12.806[J])
(Subject meets with12.306)
Prereq: 5.60 or 5.61; 18.075; or permission of instructor
Units: 3-0-9
______
Introduction to the physics and chemistry of the atmosphere including experience with computer codes. Aerosols and theories of their formation, evolution, and removal. Gas and aerosol transport from urban to continental scales. Coupled models of radiation, transport, and chemistry. Solution of inverse problems to deduce emissions and removal rates. Emissions control technology and costs. Applications to air pollution and climate.
R. G. Prinn

10.579[J] Energy Technology and Policy: From Principles to Practice
______

Graduate (Spring)
(Same subject as5.00[J],6.929[J],22.813[J])
Prereq: None
Units: 3-0-6
______
Develops analytical skills to lead a successful technology implementation with an integrated approach that combines technical, economical and social perspectives. Considers corporate and government viewpoints as well as international aspects, such as nuclear weapons proliferation and global climate issues. Discusses technologies such as oil and gas, nuclear, solar, and energy efficiency. Limited to 100.
J. Deutch

10.580 Solid-State Surface Science
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 10.213
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Structural, chemical, and electronic properties of solids and solid surfaces. Analytical tools used to characterize surfaces including Auger and photoelectron spectroscopies and electron diffraction techniques. Surface thermodynamics and kinetics including adsorption-desorption, catalytic properties, and sputtering processes. Applications to microelectronics, optical materials, and catalysis.
K. K. Gleason

10.585 Engineering Nanotechnology
______

Graduate (Fall)
Prereq: 10.302, 10.213, or permission of instructor
Units: 3-0-9
Lecture: TR12.30-2 (66-110)
______
Review of fundamental concepts of energy, mass and electron transport in materials confined or geometrically patterned at the nanoscale, where departures from classical laws are dominant. Specific applications to contemporary engineering challenges are discussed including problems in energy, biology, medicine, electronics, and material design.
M. Strano
No textbook information available

10.586 Crystallization Science and Technology
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 10.213
Units: 3-0-6
Lecture: TR11-12.30 (56-169)
______
Studies the nucleation and growth of crystals from a melt or a liquid solution and their important role in a wide range of applications, including pharmaeuticals, proteins, and semiconductor materials. Provides background information and covers topics needed to understand, perform experiments, construct and simulate mechanistic models, and design, monitor, and control crystallization processes. Limited to 30.
A. S. Myerson
No required or recommended textbooks

10.591 Case Studies in Bioengineering
______

Graduate (Fall)
Prereq: Biology (GIR) or permission of instructor
Units: 3-0-6
Lecture: T EVE (4-6 PM) (66-148) Recitation: W EVE (5 PM) (66-148)
______
Analysis and discussion of recent research in areas of bioengineering, including drug delivery, protein and tissue engineering, physiological transport, stem cell technology, and quantitative immunology by senior investigators in the Boston area. Students will read and critique papers, then have discussions with authors about their work.
C. K. Colton
No required or recommended textbooks

10.595 Molecular Design and Bioprocess Development of Immunotherapies
______

Graduate (Spring)
(Subject meets with10.495)
Prereq: Permission of instructor
Units: 3-0-6
______
Examines challenges and opportunities for applying chemical engineering principles to address the growing global burden of infectious disease, including drug-resistant strains and neglected pathogens. Topics include a historical overview of vaccines and immunotherapies, the molecular design considerations for new immunotherapies and adjuvants, the economic challenges for process development and manufacturing of immunotherapies, and new technologies for designing and assessing therapies. Case studies to cover topics for specific diseases. Students taking graduate version complete additional assignments.
J. C. Love

10.606 Visual Strategies for Scientists and Engineers
______

Graduate (Spring); first half of term
Prereq: None
Units: 1-2-2 [P/D/F]
______
Provides instruction in best practices for creating more effective graphics and photographs to support and communicate research in science and engineering. Discusses in depth specific examples from a range of scientific contexts, such as journal articles, presentations, grant submissions, and cover art. Topics include graphics for figures depicting form and structure, process, and change over time. Prepares students to create effective graphics for submissions to existing journals and calls attention to the future of published graphics with the advent of interactivity. Limited to 10.
F. Frankel

10.625[J] Electrochemical Energy Conversion and Storage: Fundamentals, Materials and Applications
______

Graduate (Fall)
(Same subject as2.625[J])
Prereq: 2.005, 3.046, 3.53, 10.40, or 2.051 and 2.06, or permission of instructor
Units: 4-0-8
Lecture: TR2.30-4 (3-333) Recitation: W4 (1-150)
______
Fundamental concepts, tools, and applications in electrochemical science and engineering. Introduces thermodynamics, kinetics and transport of electrochemical reactions. Describes how materials structure and properties affect electrochemical behavior of particular applications, for instance in lithium rechargeable batteries, electrochemical capacitors, fuel cells, photo electrochemical cells, and electrolytic cells. Discusses state-of-the-art electrochemical energy technologies for portable electronic devices, hybrid and plug-in vehicles, electrical vehicles. Theoretical and experimental exploration of electrochemical measurement techniques in cell testing, and in bulk and interfacial transport measurements (electronic and ionic resistivity and charge transfer cross the electrode-electrolyte interface).
Y. Shao-Horn
No textbook information available

10.626 Electrochemical Energy Systems
______

Graduate (Spring)
(Subject meets with10.426)
Prereq: 10.50 or permission of instructor
Units: 3-0-9
______
Introduces principles and mathematical models of electrochemical energy conversion and storage. Studies equivalent circuits, thermodynamics, reaction kinetics, transport phenomena, electrostatics, porous media, and phase transformations. Includes applications to batteries, fuel cells, supercapacitors, and electrokinetics. Students taking graduate version complete additional assignments.
M. Z. Bazant

10.631 Structural Theories of Polymer Fluid Mechanics
______

Graduate (Spring)
Prereq: 10.301
Units: 3-0-6
______
Structural and molecular models for polymeric liquids. Nonequilibrium properties are emphasized. Elementary kinetic theory of polymer solutions. General phase space kinetic for polymer melts and solutions. Network theories. Interrelations between structure and rheological properties.
R. C. Armstrong

10.637[J] Quantum Chemical Simulation
______

Graduate (Fall)
(Same subject as5.698[J])
(Subject meets with5.697[J],10.437[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (14-0637)
______
Addresses both the theory and application of first-principles computer simulations methods (i.e., quantum, chemical, or electronic structure), including Hartree-Fock theory, density functional theory, and correlated wavefunction methods. Covers enhanced sampling, ab initio molecular dynamics, and transition-path-finding approaches as well as errors and accuracy in total and free energies. Discusses applications such as the study and prediction of properties of chemical systems, including heterogeneous, molecular, and biological catalysts (enzymes), and physical properties of materials. Students taking graduate version complete additional assignments.
H. J. Kulik
Textbooks (Fall 2016)

10.643[J] Future Medicine: Drug Delivery, Therapeutics, and Diagnostics
______

Graduate (Spring)
(Same subject asHST.526[J])
(Subject meets with10.443)
Prereq: 5.12 or permission of instructor
Units: 3-0-6
______
Aims to describe the direction and future of medical technology. Introduces pharmaceutics, pharmacology, and conventional medical devices, then transitions to drug delivery systems, mechanical/electric-based and biological/cell-based therapies, and sensors. Covers nano- and micro drug delivery systems, including polymer-drug conjugates, protein therapeutics, liposomes and polymer nanoparticles, viral and non-viral genetic therapy, and tissue engineering. Previous coursework in cell biology and organic chemistry recommended. Students taking graduate version complete additional assignments. Limited to 40.
D. G. Anderson

10.644[J] Frontiers in Therapeutics and Drug Delivery
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject asHST.914[J])
Prereq: 7.05 or permission of instructor
Units: 3-0-6
______
Provides an introduction to pharmaceutics and conventional oral, injected, transdermal and inhaled drug delivery systems. Includes studies of drug delivery devices and systems, e.g., stents, pumps, depo systems, responsive drug delivery systems, and biological/cell based therapies. Covers nano- and micro drug delivery systems, including polymer-drug conjugates, modified proteins, liposomes and polymer nanoparticles, viral and non-viral genetic therapy, and microencapsulated vaccines. Discusses reviews and current technology. Students taking graduate version complete additional assignments. Limited to 40.
D. G. Anderson

10.65 Chemical Reactor Engineering
______

Graduate (Spring)
Prereq: 10.37 or permission of instructor
Units: 4-0-8
URL: https://web.mit.edu/10.65/www/
______
Fundamentals of chemically reacting systems with emphasis on synthesis of chemical kinetics and transport phenomena. Topics include kinetics of gas, liquid, and surface reactions; quantum chemistry; transition state theory; surface adsorption, diffusion, and desorption processes; mechanism and kinetics of biological processes; mechanism formulation and sensitivity analysis. Reactor topics include nonideal flow reactors, residence time distribution and dispersion models; multiphase reaction systems; nonlinear reactor phenomena. Examples are drawn from different applications, including heterogeneous catalysis, polymerization, combustion, biochemical systems, and materials processing.
M. Strano, G. Stephanopoulos

10.652[J] Kinetics of Chemical Reactions
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as5.68[J])
Prereq: 5.62, 10.37, or 10.65
Units: 3-0-6
URL: http://web.mit.edu/10.652/www/
Lecture: TR11-12.30 (56-114)
______
Experimental and theoretical aspects of chemical reaction kinetics, including transition-state theories, molecular beam scattering, classical techniques, quantum and statistical mechanical estimation of rate constants, pressure-dependence and chemical activation, modeling complex reacting mixtures, and uncertainty/ sensitivity analyses. Reactions in the gas phase, liquid phase, and on surfaces are discussed with examples drawn from atmospheric, combustion, industrial, catalytic, and biological chemistry.
W. H. Green
Textbooks (Fall 2016)

10.668[J] Statistical Mechanics of Polymers
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as3.941[J])
Prereq: 10.568 or permission of instructor
Units: 3-0-9
______
Concepts of statistical mechanics and thermodynamics applied to macromolecules: polymer conformations in melts, solutions, and gels; Rotational Isomeric State theory, Markov processes and molecular simulation methods applied to polymers; incompatibility and segregation in incompressible and compressible systems; molecular theory of viscoelasticity; relation to scattering and experimental measurements.
G. C. Rutledge, A. Alexander-Katz

10.677 Topics in Applied Microfluidics
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 10.301 or permission of instructor.
Units: 3-0-6
______
Provides an introduction to the field of microfluidics. Reviews fundamental concepts in transport phenomena and dimensional analysis, focusing on new phenomena which arise at small scales. Discusses current applications, with an emphasis on the contributions engineers bring to the field. Local and visiting experts in the field discuss their work. Limited to 30.
P. Doyle

10.689 Concepts in Modern Heterogeneous Catalysis
______

Graduate (Spring)
Not offered regularly; consult department
(Subject meets with10.489)
Prereq: 10.37, 10.302
Units: 3-0-6
______
Explores topics in the design and implementation of heterogeneous catalysts for chemical transformations. Emphasizes use of catalysis for environmentally benign and sustainable chemical processes. Lectures address concepts in catalyst preparation, catalyst characterization, quantum chemical calculations, and microkinetic analysis of catalytic processes. Shows how experimental and theoretical approaches can illustrate important reactive intermediates and transition states involved in chemical reaction pathways, and uses that information to help identify possible new catalysts that may facilitate reactions of interest. Draws examples from current relevant topics in catalysis. Includes a group project in which students investigate a specific topic in greater depth. Students taking graduate version complete additional assignments.
Y. Roman

10.702[J] Introduction to Experimental Biology and Communication
______

Undergrad (Fall, Spring) Institute Lab
(Same subject as7.02[J])
Prereq: Biology (GIR)
Units: 4-8-6
1st mtg 9/8 mandatory. Lecture: TR11 (32-155) Lab: TR1-5 (68-074) or WF1-5 (68-074) Recitation: M9-11 (68-121) or M1-3 (66-148, 4-146) or T9-11 (4-144) or W1-3 (68-121) or W9-11 (68-121) +final
______
Introduction to the experimental concepts and methods of molecular biology, biochemistry, and genetic analysis. Emphasis on experimental design, critical data analysis, and the development of written communications skills. 12 units may be applied to the General Institute Laboratory Requirement. Concurrent registration with 7.03 strongly recommended. Enrollment limited.
Fall:T. Baker, M. Gehring, K. D. Wittrup
Spring:T. Baker, O. Yilmaz, K. D. Wittrup
No required or recommended textbooks

10.792[J] Global Operations Leadership Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as2.890[J],15.792[J],16.985[J])
Prereq: None
Units arranged [P/D/F]
Lecture: M EVE (4-6 PM) (E62-262)
______
Integrative forum in which worldwide leaders in business, finance, government, sports, and education share their experiences and insights with students aspiring to run global operations. Students play a large role in managing the seminar. Preference to LGO students.
T. Roemer
No textbook information available

10.805[J] Technology, Law, and the Working Environment
(New)
______

Graduate (Spring)
Not offered regularly; consult department
(Same subject asIDS.436[J])
(Subject meets with1.802[J],1.812[J],11.022[J],11.631[J],IDS.431[J])
Prereq: Permission of instructor
Units: 3-0-6
______
Addresses relationship between technology-related problems and the law applicable to work environment. National Labor Relations Act, Occupational Safety and Health Act. Toxic Substances Control Act, state worker's compensation, and suits by workers in the courts discussed. Problems related to occupational health and safety, collective bargaining as a mechanism for altering technology in the workplace, job alienation, productivity, and the organization of work addressed. Prior courses or experience in the environmental, public health, or law-related areas.
N. A. Ashford, C. C. Caldart

10.806 Management in Engineering
______

Undergrad (Fall)
Engineering School-Wide Elective Subject.
(Offered under:2.96,6.930,10.806,16.653)
Prereq: None
Units: 3-1-8
Lecture: MW11-12.30 (35-225) Lab: M4 (35-308) or T10 (1-273) or R4 (1-371) or F1 (1-132) or F2 (1-132)
______
Introduction and overview of engineering management. Financial principles, management of innovation, technical strategy and best management practices. Case study method of instruction emphasizes participation in class discussion. Focus is on the development of individual skills and management tools. Restricted to juniors and seniors.
H. S. Marcus, J.-H. Chun
No textbook information available

10.807[J] Innovation Teams
______

Graduate (Fall, Spring)
(Same subject as15.371[J])
Prereq: 15.911 or permission of instructor
Units: 4-4-4
Lecture: W11-2 (32-144) Lab: F9-11.30 (32-155)
______
Students work in teams to develop commercialization strategies for innovative research projects generated in MIT laboratories. Projects cover critical aspects of commercialization, from selecting the target application and market for the technology to developing an intellectual property strategy and performing a competitive analysis. Instruction provided in communication and teamwork skills, as well as analysis of the challenges and benefits of technology transfer. Includes lectures, guest speakers, and extensive team coaching. Designed primarily for students in engineering, science, and management. Applications, resumes, and a brief statement of interest are required prior to registration.
F. Murray, L. Perez-Breva, N. Afeyan
No textbook information available

10.817[J] Atmospheric Chemistry
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as1.84[J],12.807[J])
Prereq: 5.60
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Provides a detailed overview of the chemical transformations that control the abundances of key trace species in the Earth's atmosphere. Emphasizes the effects of human activity on air quality and climate. Topics include photochemistry, kinetics, and thermodynamics important to the chemistry of the atmosphere; stratospheric ozone depletion; oxidation chemistry of the troposphere; photochemical smog; aerosol chemistry; and sources and sinks of greenhouse gases and other climate forcers.
J. H. Kroll

School of Chemical Engineering Practice

10.80 (10.82, 10.84, 10.86) School of Chemical Engineering Practice -- Technical Accomplishment
______

Graduate (Fall, Spring, Summer)
Prereq: None
Units: 0-6-0
10.80: TBA.
10.82: TBA.
10.84: TBA.
10.86: TBA.
______
Conducted at industrial field stations of the School of Chemical Engineering Practice. Group problem assignments include process development design, simulation and control, technical service, and new-product development. Grading based on technical accomplishment. Credit granted in lieu of master's thesis. See departmental descripton on School of Chemical Engineering Practice for details. Enrollment limited and subject to plant availability.
T. A. Hatton
10.80: No textbook information available
10.82: No textbook information available
10.84: No textbook information available
10.86: No textbook information available

10.81 (10.83, 10.85, 10.87) School of Chemical Engineering Practice -- Communication Skills and Human Relations
______

Graduate (Fall, Spring, Summer)
Prereq: None
Units: 0-6-0
10.81: TBA.
10.83: TBA.
10.85: TBA.
10.87: TBA.
______
Conducted at industrial field stations of the School of Chemical Engineering Practice. Group problem assignments include process development, design, simulation and control, technical service, and new-product development. Grading based on communication skills and human relations in group assignments. Credit granted in lieu of master's thesis; see departmental description on School of Chemical Engineering Practice for details. Enrollment limited and subject to plant availability.
T. A. Hatton
10.81: No textbook information available
10.83: No textbook information available
10.85: No textbook information available
10.87: No textbook information available


left arrow|10.00-10.899|10.90-10.999 plus THG, THU, UROP, UPOP|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 10: Chemical Engineering
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Course 10: Chemical Engineering
Fall 2016


General

10.90 Independent Research Problem
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
For special and graduate students who wish to carry out some minor investigation in a particular field. Subject and hours to fit individual requirements.
R. D. Braatz
No textbook information available

10.910 Independent Research Problem
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No textbook information available

10.911 Independent Research Problem
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
For undergraduate students who wish to carry out a special investigation in a particular field. Topic and hours arranged.
B. S. Johnston
No textbook information available

10.953 Seminar in Heterogeneous Catalysis
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: R12-2 (E17-517)
______
Students present their research to other students and staff. Research topics include heterogeneous catalysis, design of catalytic materials, biomass conversion, biofuels, and CO2 utilization.
Y. Roman
No required or recommended textbooks

10.954 Seminar in Applied Optical Spectroscopy
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: T2-4 (66-360)
______
Research seminars given by students, postdocs, and visitors. Topics covered include applied optical spectroscopy and imaging, with particular emphasis on nanomaterials and how they relate to alternative energy technologies.
W. A. Tisdale
No required or recommended textbooks

10.955 Seminar in Electrochemical Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: R EVE (4-6 PM) (66-360)
______
Designed to allow students to present and discuss their research in the area of electrochemical engineering with a particular emphasis on energy storage and conversion (e.g., batteries, fuel cells, electroreactors). Specific topics include active materials design, electroanalytical platform development, and integration of electrochemical and imaging techniques.
F. R. Brushett
No required or recommended textbooks

10.956 Seminar in Atomistic Simulation
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W3-5 (66-269)
______
Seminar allows students to present their research to other students and staff. The research topics include electronic structure theory, computational chemistry techniques, and density functional theory with a focus on applications to catalysis and materials science.
H. J. Kulik
No required or recommended textbooks

10.957 Seminar in Bioengineering Technology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W9-11 (46-5305)
______
Research seminars presented by students and guest speakers on emerging biotechnologies.
K. Chung
No required or recommended textbooks

10.958 Seminar in the Fluid Mechanics and Self-assembly of Soft Matter
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: M EVE (4-6 PM) (66-319)
______
Covers topics related to low Reynolds number hydrodynamics and the statistical physics of particulate media. Specifics include the kinetics of phase transitions in soft matter and the time-varying deformation of colloidal dispersions, glasses and gels.
J. W. Swan
No required or recommended textbooks

10.960[J] Seminar in Polymers and Soft Matter
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as3.903[J])
Prereq: None
Units: 2-0-0 [P/D/F]
Lecture: W3-5 (56-114)
______
A series of seminars covering a broad spectrum of topics in polymer science and engineering, featuring both on- and off-campus speakers.
A. Alexander-Katz, R. E. Cohen, D. Irvine
No required or recommended textbooks

10.961 Seminar in Advanced Air Pollution Research
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
______
Research seminars, presented by students engaged in thesis work in the field of air pollution. Particular emphasis given to atmospheric chemistry, mathematical modeling, and policy analysis.
G. J. McRae

10.962 Seminar in Molecular Cell Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: TR9.30-11
______
Weekly seminar with discussion of ongoing research and relevant literature by graduate students, postdoctoral fellows, and visiting scientists on issues at the interface of chemical engineering with molecular cell biology. Emphasis is on quantitative aspects of physicochemical mechanisms involved in receptor/ligand interactions, receptor signal transduction processes, receptor-mediated cell behavioral responses, and applications of these in biotechnology and medicine.
D. A. Lauffenburger
No required or recommended textbooks

10.964 Seminar on Transport Theory
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Class begins at 12:15. Lecture: M12-2.30 (66-360)
______
Research seminars presented by students and guest speakers on mathematical modeling of transport phenomena, focusing on electrochemical systems, electrokinetics, and microfluidics.
M. Z. Bazant
No required or recommended textbooks

10.965 Seminar in Biosystems Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: T9-11 (76-258)
______
Advanced topics on the state-of-the-art in design and implementation of analytical processes for biological systems, including single-cell analysis, micro/nanotechnologies, systems biology, biomanufacturing, and process engineering. Seminars and discussions guided by the research interests of participating graduate students, postdoctoral associates, faculty, and visiting lecturers.
J. C. Love
No required or recommended textbooks

10.966 Seminar in Drug Delivery, Biomaterials, and Tissue Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W12-2 (76-659)
______
Focuses on presentations by students and staff on current research in the area of drug delivery, biomaterials, and tissue engineering. Includes topics such as nanotherapeutics, intracellular delivery, and therapies for diabetes.
D. G. Anderson
No required or recommended textbooks

10.967 Seminar in Protein-Polymer Materials Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: F9-11 (66-319)
______
Research seminar covers topics on protein-based polymeric materials. Specific topics include bioelectronic materials, protein-polymer hybrids, and nanostructured proteins and polymers.
B. D. Olsen
No required or recommended textbooks

10.968 Seminar in Biomolecular Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W9-11 (E17-517)
______
Covers research progress in the area of design, testing and mechanistic investigation of novel molecular systems for biotechnological applications.
H. D. Sikes
No required or recommended textbooks

10.969 Molecular Engineering Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W2-4 (E17-517)
______
Seminar allows students to present their research to other students and staff. Research topics include molecular simulations techniques and applications, and molecular engineering of pharmaceutical and biopharmaceutical processes and formulations.
B. L. Trout
No required or recommended textbooks

10.970 Seminar in Molecular Computation
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W12-2 (E17-517)
______
Seminar allows students to present their research to other students and staff. The research topics include computational chemistry techniques, kinetics, and catalysis. Focus is on molecular-level understanding of chemical change.
W. H. Green
No required or recommended textbooks

10.971 Seminar in Fluid Mechanics and Transport Phenomena
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: R EVE (4-6 PM) (E17-517)
______
Seminar series on current research on Newtonian and non-Newtonian fluid mechanics and transport phenomena, and applications to materials processing. Seminars given by guest speakers and research students.
P. S. Doyle, G. H. McKinley, J. W. Swan
No required or recommended textbooks

10.972 Biochemical Engineering Research Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
______
Seminar allows students to present their research programs to other students and staff. The research topics include fermentation and enzyme technology, mammalian and animal cell cultivation, and biological product separation.
D. I. C. Wang, C. L. Cooney

10.973 Bioengineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: F1-3 (66-480)
______
Seminar covering topics related to current research in the application of chemical engineering principles to biomedical science and biotechnology.
C. K. Colton
No required or recommended textbooks

10.974 Seminar in Chemical Engineering Nanotechnology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: R EVE (5.30-7.30 PM) (66-110)
______
Seminar covering topics related to current research in the application of chemical engineering principles to nanotechnology. Limited to 30.
M. S. Strano
No required or recommended textbooks

10.975 Seminar in Polymer Science and Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: T12-2 (76-559) or T12.30-2.30 (E17-517) or T12-2 (66-360)
______
Research seminars, presented by students engaged in thesis work in the field of polymers and by visiting lecturers from industry and academia.
R. E. Cohen, P. T. Hammond, G. C. Rutledge
No required or recommended textbooks

10.976 Process Design, Operations, and Control
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: R4-5.30 (66-319)
______
Seminars on the state of the art in design, operations, and control of processing systems, with emphasis on computer-based tools. Discussions guided by the research interests of participating students. Topics include mathematical and numerical techniques, representational methodologies, and software development.
P. I. Barton
No required or recommended textbooks

10.981 Seminar in Colloid and Interface Science
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W3.30-5.30 (66-480)
______
Review of current topics in colloid and interface science. Topics include statistical mechanics and thermodynamics of micellar solutions, self-assembling systems, and microemulsions; solubilization of simple ions, amino acids, and proteins in reversed micelles; enzymatic reactions in reversed micelles; phase equilibria in colloidal systems; interfacial phenomena in colloidal systems; biomedical aspects of colloidal systems.
D. Blankschtein
No required or recommended textbooks

10.982 Seminar in Experimental Colloid and Surface Chemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: T EVE (4-6 PM) (66-360)
______
In-depth discussion of fundamental physical relationships underlying techniques commonly used in the study of colloids and surfaces with a focus on recent advances and experimental applications. Topics have included the application of steady-state and time-resolved fluorescence spectroscopies, infrared spectroscopy, and scanning probe microscopies.
T. A. Hatton
No required or recommended textbooks

10.983 Reactive Processing and Microfabricated Chemical Systems
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W EVE (4-6 PM) (66-360)
______
Advanced topics in synthesis of materials through processes involving transport phenomena and chemical reactions. Chemical vapor deposition, modeling, and experimental approaches to kinetics of gas phase and surface reactions, transport phenomena in complex systems, materials synthesis, and materials characterization. Design fabrication and applications of microfabricated chemical systems. Seminars by graduate students, postdoctoral associates, participating faculty, and visiting lecturers.
K. F. Jensen
No required or recommended textbooks

10.984 Biomedical Applications of Chemical Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W EVE (5-6.30 PM) (76-156)
______
Weekly seminar with lectures on current research by graduate students, postdoctoral fellows, and visiting scientists on topics related to biomedical applications of chemical engineering. Specific topics include polymeric controlled release technology, extracorporal reactor design, biomedical polymers, bioengineering aspects of pharmaceuticals, and biomaterials/tissue and cell interactions.
R. S. Langer
No required or recommended textbooks

10.985 Seminar in Materials Systems Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: M12 (E17-517)
______
Focuses on the state of the art in the systems engineering of materials products and materials manufacturing processes. Addresses topics such as pharmaceuticals manufacturing, polymeric drug delivery systems, and nano- and microstructured materials. Discussions guided by the research interests of participating students. Includes techniques from applied mathematics and numerical methods, multiscale systems analysis, and control theory.
R. D. Braatz
No required or recommended textbooks

10.987 Solid Thin Films and Interfaces
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W2.30-4 (66-360)
______
Current research topics and fundamental issues relating to the deposition and properties of solid thin films and interfaces. Emphasis on applying analytical techniques, such as solid-state NMR, to explore the thermodynamics and kinetics of growth, defect formation, and structural modification incurred during film growth and post processing.
K. K. Gleason
No required or recommended textbooks

10.989 Seminar in Biotechnology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: R12-2 (66-360)
______
Research seminars, presented by graduate students and visitors from industry and academia, covering a broad range of topics of current interest in biotechnology. Discussion focuses on generic questions with potential biotechnological applications and the quest for solutions through a coordinated interdisciplinary approach.
Gr. Stephanopoulos
No required or recommended textbooks

10.990 Introduction to Chemical Engineering Research
______

Graduate (Fall)
Prereq: None
Units: 2-4-0 [P/D/F]
Lecture: TR2 (66-110) Lab: W3 (66-110)
______
Introduction to research in chemical engineering by faculty of chemical engineering department. Focus is on recent developments and research projects available to new graduate students.
P. T. Hammond, P. S. Doyle
No required or recommended textbooks

10.991 Seminar in Chemical Engineering
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: MF3-4.30 (66-110)
______
No required or recommended textbooks

10.992 Seminar in Chemical Engineering
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
______
For students working on doctoral theses.
K. F. Jensen

10.994 Molecular Bioengineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: R12-1.30 (76-261D)
______
Presentations and discussion by graduate students, postdoctoral fellows, and visiting scientists of current literature and research on the engineering of protein biopharmaceuticals. Topics include combinatorial library construction and screening strategies, antibody engineering, gene therapy, cytokine engineering, and immunotherapy engineering strategies.
K. D. Wittrup
No required or recommended textbooks

10.995 Cellular and Metabolic Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: T9-11 (E17-517)
______
Graduate students, postdoctoral fellows, visiting scientists, and guest industrial practitioners to present their own research and highlight important advances from the literature in biochemical and bioprocess engineering. Topics of interest include metabolic engineering, novel microbial pathway design and optimization, synthetic biology, and applications of molecular biology to bioprocess development.
K. J. Prather
No required or recommended textbooks

10.997 Theoretical and Computational Immunology Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: F12.30-3 (E25-202)
______
Presentations and discussions of current literature and research in theoretical and computational immunology. Topics include T cell biology, cell-cell recognition in immunology, polymers and membranes, and statistical mechanics.
Arup K. Chakraborty
No required or recommended textbooks

10.998 Seminar in Crystallization Science and Technology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: W2-4 (E17-517)
______
Focuses on current topics related to crystallization science and technology in the chemical, pharmaceutical and food industries. Discusses fundamental work on nucleation, polymorphism, impurity crystal interactions and nano-crystal formation, along with industrial applications of crystallization.
A. S. Myerson
No required or recommended textbooks

10.EPE UPOP Engineering Practice Experience
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.EPE,2.EPE,3.EPE,6.EPE,10.EPE,16.EPE,22.EPE)
Prereq: 2.EPW or permission of instructor
Units: 0-0-1 [P/D/F]
TBA.
______
Provides sophomores with guided practice in finding opportunities and excelling in the world of practice. Building on the skills and relationships acquired in the Engineering Practice Workshop, students receive coaching to articulate goals, invoke the UPOP network of mentors and employers, identify and pursue opportunities and negotiate terms of their summer assignment. Students complete a 10-12 week internship, which includes filing three progress reports, conducting one informational interview, and possibly hosting a site visit by MIT staff. Returning to campus as juniors, UPOP students take part in reflective exercises that aid assimilation of learning objectives and reinforce the cognitive link between all aspects of the UPOP experience and disciplinary fields of study. Sequence begins in the spring of sophomore year and ends in the fall of junior year.
Staff
No textbook information available

10.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No textbook information available

10.S94 Special Problems in Chemical Engineering
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Focuses on problem of current interest not covered in regular curriculum; topic varies from year to year.
Staff
No textbook information available

10.S95 Special Problems in Chemical Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Focuses on problem of current interest not covered in regular curriculum; topic varies from year to year.
Staff
No textbook information available

10.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of an SM, PhD, or ScD thesis; to be arranged by the student and appropriate MIT faculty member.
D. Blankschtein
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

10.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Program of research leading to writing an SB thesis; topic arranged between student and MIT faculty member.
B. S. Johnston
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

10.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

10.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Opportunity for participation in a research group, or for special investigation in a particular field. Topic and hours to fit individual requirements.
B. S. Johnston
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|10.00-10.899|10.90-10.999 plus THG, THU, UROP, UPOP|right arrow



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Fall 2016 Course 11: Urban Studies and Planning
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Course 11: Urban Studies and Planning
Fall 2016


Introductory Subjects

11.001[J] Introduction to Urban Design and Development
______

Undergrad (Fall) HASS Humanities
(Same subject as4.250[J])
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4250
Lecture: MW11-12.30 (2-105) +final
______
Examines the evolving structure of cities and the way that cities, suburbs, and metropolitan areas can be designed and developed. Surveys the ideas of a wide range of people who have addressed urban problems. Stresses the connection between values and design. Demonstrates how physical, social, political and economic forces interact to shape and reshape cities over time.
L. Vale
No required or recommended textbooks

11.002[J] Making Public Policy
______

Undergrad (Fall) HASS Social Sciences Communication Intensive HASS
(Same subject as17.30[J])
Prereq: None
Units: 4-0-8
URL: http://web.mit.edu/17.30j/www/
Lecture: MW9.30-11 (4-237) Recitation: R3 (66-148) or R4 (66-148) or F11 (1-134) or F12 (1-134)
______
Examines how the struggle among competing advocates shapes the outputs of government. Considers how conditions become problems for government to solve, why some political arguments are more persuasive than others, why some policy tools are preferred over others, and whether policies achieve their goals. Investigates the interactions among elected officials, think tanks, interest groups, the media, and the public in controversies over global warming, urban sprawl, Social Security, health care, education, and other issues.
Staff
No textbook information available

11.003[J] Methods of Policy Analysis
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Social Sciences
(Same subject as17.303[J])
Prereq: 11.002J;Coreq: 14.01
Units: 3-0-9
______
Provides students with an introduction to public policy analysis. Examines various approaches to policy analysis by considering the concepts, tools, and methods used in economics, political science, and other disciplines. Students apply and critique these approaches through case studies of current public policy problems.
Staff

11.005 Introduction to International Development
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-0-9
______
Introduces the political economy of international economic development planning, using an applied, quantitative approach. Considers why some countries are able to develop faster than others. Presents major theories and models of development and underdevelopment, providing tools to understand the mechanisms and processes behind economic growth and broader notions of progress. Offers an alternative view of development, focusing on the persistence of dichotomies in current theory and practice. Using specific cases, explores how different combinations of actors and institutions at various scales may promote or inhibit economic development. Students re-examine conventional knowledge and engage critically with the assumptions behind current thinking and policy.
Y. Hong, C. Cardoso

11.006 Poverty and Economic Security
______

Not offered academic year 2017-2018Undergrad (Fall) HASS Social Sciences
(Subject meets with11.206)
Prereq: None
Units: 3-0-9
Lecture: TR9.30-11 (9-255)
______
Explores the evolution of poverty and economic security in the US within a global context. Examines the impacts of recent economic restructuring and globalization. Reviews current debates about the fate of the middle class, sources of increasing inequality, and approaches to advancing economic opportunity and security. Students taking graduate version complete additional assignments.
A. Glasmeier
No textbook information available

11.011 The Art and Science of Negotiation
______

Undergrad (Fall, Spring) HASS Social Sciences
Prereq: None
Units: 3-0-9
URL: http://dusp.mit.edu/subject/spring-2016-11011
Lecture: MW3-4.30 (9-255)
______
Introduction to negotiation theory and practice. Applications in government, business, and nonprofit settings are examined. Combines a "hands-on" personal skill-building orientation with a look at pertinent theory. Strategy, communications, ethics, and institutional influences are examined as they shape the ability of actors to analyze problems, negotiate agreements, and resolve disputes in social, organizational, and political circumstances characterized by interdependent interests.
B. Verdini
No textbook information available

11.013[J] American Urban History I
______

Undergrad (Fall) HASS Humanities Communication Intensive HASS
(Same subject as21H.217[J])
Prereq: None
Units: 2-0-7
Lecture: T2-4 (9-217)
______
Seminar on the history of institutions and institutional change in American cities from roughly 1850 to the present. Among the institutions to be looked at are political machines, police departments, courts, schools, prisons, public authorities, and universities. Focuses on readings and discussions.
R. M. Fogelson
No textbook information available

11.014[J] American Urban History II
______

Undergrad (Fall) HASS Humanities Communication Intensive HASS
(Same subject as21H.218[J])
Prereq: None
Units: 2-0-7
Lecture: R2-4 (9-450A)
______
Seminar on the history of selected features of the physical environment of urban America. Among the features considered are parks, cemeteries, tenements, suburbs, zoos, skyscrapers, department stores, supermarkets, and amusement parks.
R. M. Fogelson
Textbooks (Fall 2016)

11.015[J] Riots, Strikes, and Conspiracies in American History
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Humanities Communication Intensive HASS
(Same subject as21H.226[J])
Prereq: None
Units: 3-0-9
______
Focuses on a series of short, complicated, traumatic events that shed light on American politics, culture, and society. Events studied may include the rendition of Anthony Burns in 1854, the most famous fugitive slave controversy in US history; the Homestead strike/lockout of 1892; the quiz show scandal of the 1950s; and the student uprisings at Columbia University in 1968. Emphasis on finding ways to make sense of these events and on using them to understand larger processes of change in American history.
R. M. Fogelson

11.016[J] The Once and Future City
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Humanities Communication Intensive HASS
(Same subject as4.211[J])
Prereq: None
Units: 3-0-9
______
Examines the evolving structure of cities, the dynamic processes that shape them, and the significance of a city's history for its future development. Develops the ability to read urban form as an interplay of natural processes and human purposes over time. Field assignments in Boston provide the opportunity to use, develop, and refine these concepts. Enrollment limited.
A. Spirn

11.021[J] Environmental Law, Policy, and Economics: Pollution Prevention and Control
______

Undergrad (Fall) HASS Social Sciences
(Same subject as1.801[J],17.393[J])
(Subject meets with1.811[J],11.630[J],IDS.430[J])
Prereq: None
Units: 3-0-9
Credit cannot also be received for15.663
Lecture: TR3.30-5 (E51-057) +final
______
Introduction to important issues in contemporary environmental law, policy, and economics. Discusses the roles and interactions of Congress, federal agencies, state governments, and the courts in dealing with environmental problems. Topics include common law, administrative law, environmental impact assessments required by the National Environmental Policy Act, and legislation and court decisions dealing with air pollution, water pollution, the control of hazardous waste, pollution and accident prevention, the production and use of toxic chemicals, community right-to-know, and environmental justice. Explores the role of science and economics in legal decisions, and economic incentives as an alternative or supplement to regulation. Analyzes pollution as an economic problem and a failure of markets. Introduction to basic legal skills: how to read and understand cases, regulation, and statutes; how to discover the current state of the law in a specific area; and how to take action toward resolution of environmental problems. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C. Caldart
Textbooks (Fall 2016)

11.022[J] Regulation of Chemicals, Radiation, and Biotechnology
______

Undergrad (Spring)
Not offered regularly; consult department
(Same subject as1.802[J])
(Subject meets with1.812[J],10.805[J],11.631[J],IDS.431[J],IDS.436[J])
Prereq: 1.801 or permission of instructor
Units: 3-0-9
______
Focuses on policy design and evaluation in the regulation of hazardous substances and processes. Includes risk assessment, industrial chemicals, pesticides, food contaminants, pharmaceuticals, radiation and radioactive wastes, product safety, workplace hazards, indoor air pollution, biotechnology, victims' compensation, and administrative law. Health and economic consequences of regulation, as well as its potential to spur technological change, are discussed for each regulatory regime. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C. Caldart

11.025[J] D-Lab: Development
______

Undergrad (Fall) HASS Social Sciences
(Same subject asEC.701[J])
(Subject meets with11.472[J],EC.781[J])
Prereq: None
Units: 3-2-7
Lecture: MWF3.30-5 (N51-310)
______
Issues in international development, appropriate technology and project implementation addressed through lectures, case studies, guest speakers and laboratory exercises. Students form project teams to partner with community organizations in developing countries, and formulate plans for an optional IAP site visit. (Previous field sites include Ghana, Brazil, Honduras and India.) Recitation sections focus on specific project implementation, and include cultural, social, political, environmental and economic overviews of the target countries as well as an introduction to the local languages. Enrollment limited by lottery; must attend first class session.
S. L. Hsu, A. B. Smith, B. Sanyal
No textbook information available

11.026[J] Downtown
______

Undergrad (Spring) HASS Humanities
(Same subject as21H.321[J])
(Subject meets with11.339)
Prereq: None
Units: 2-0-7
______
Seminar on downtown in US cities from the late 19th century to the late 20th. Emphasis on downtown as an idea, place, and cluster of interests, on the changing character of downtown, and on recent efforts to rebuild it. Considers subways, skyscrapers, highways, urban renewal, and retail centers. Focus on readings, discussions, and individual research projects. Students taking graduate version complete additional assignments.
R. M. Fogelson

11.027 City to City: Comparing, Researching and Writing about Cities
______

Undergrad (Spring) HASS Social Sciences
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces client-oriented research and the use of urban planning tools. Students work directly with government and community agencies to find solutions to real world problems; interview planners and other field experts, and write and present findings to client and community audiences. Opportunity to travel for research. Limited to 14; preference to Course 11 majors.
C. Abbanat

Specialized Subjects

11.123 Big Plans and Mega-Urban Landscapes
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-0-6
______
Explores the physical, ecological, technological, political, economic and cultural implications of big plans and mega-urban landscapes in a global context. Uses local and international case studies to understand the process of making major changes to urban landscape and city fabric, and to regional landscape systems. Includes lectures by leading practitioners. Assignments consider planning and design strategies across multiple scales and time frames.
L. Shi

11.124 Introduction to Education: Looking Forward and Looking Back on Education
______

Undergrad (Fall) HASS Social Sciences Communication Intensive HASS
Prereq: None
Units: 3-6-3
URL: https://moodle.mit.edu/course/view.php?id=7
Lecture: TR2.30-4 (56-154)
______
One of two introductory subjects on teaching and learning science and mathematics in a variety of K-12 settings. Topics include education and media, education reform, the history of education, simulations, games, and the digital divide. Students gain practical experience through weekly visits to schools, classroom discussions, selected readings, and activities to develop a critical and broad understanding of past and current forces that shape the goals and processes of education, and explores the challenges and opportunities of teaching. Students work collaboratively and individually on papers, projects, and in-class presentations.
E. Klopfer
No textbook information available

11.125 Introduction to Education: Understanding and Evaluating Education
______

Undergrad (Spring) HASS Social Sciences Communication Intensive HASS
Prereq: None
Units: 3-6-3
______
One of two introductory subjects on teaching and learning science and mathematics in a variety of K-12 settings. Topics include student misconceptions, formative assessment, standards and standardized testing, multiple intelligences, and educational technology. Students gain practical experience through weekly visits to schools, classroom discussions, selected readings, and activities to develop a critical and broad understanding of past and current forces that shape the goals and processes of education, and explores the challenges and opportunities of teaching. Students work collaboratively and individually on papers, projects, and in-class presentations.
E. Klopfer

11.127[J] Design and Development of Games for Learning
______

Undergrad (Spring) HASS Humanities
(Same subject asCMS.590[J])
(Subject meets with11.252[J],CMS.863[J])
Prereq: None
Units: 3-6-3
______
Immerses students in the process of building and testing their own digital and board games in order to better understand how we learn from games. Explores the design and use of games in the classroom in addition to research and development issues associated with computer-based (desktop and handheld) and non-computer-based media. In developing their own games, students examine what and how people learn from them (including field testing of products), as well as how games can be implemented in educational settings. All levels of computer experience welcome. Students taking graduate version complete additional assignments.
E. Klopfer

11.129 Educational Theory and Practice I
______

Undergrad (Fall) HASS Social Sciences
Prereq: None.Coreq: 11.124
Units: 3-0-9
URL: https://sites.google.com/site/miteducationaltheorypractice/
Lecture: TR4-5.30 (1-134)
______
Concentrates on core set of skills and knowledge necessary for teaching in secondary schools. Topics include classroom management, student behavior and motivation, curriculum design, educational reform, and the teaching profession. Classroom observation is a key component. Assignments include readings from educational literature, written reflections on classroom observations, practice teaching and constructing curriculum. The first of the three-course sequence necessary to complete the Teacher Education Program. Limited to 15; preference to juniors and seniors.
G. Schwanbeck
No textbook information available

11.130 Educational Theory and Practice II
______

Undergrad (IAP)
Prereq: 11.129
Units: 3-0-9
______
Concentrates on the theory and psychology associated with student learning. Topics include educational theory, educational psychology, and theories of learning. Students assume responsibility for full-time teaching of two or more classes at their designated school. Class sessions focus on debriefing and problem-solving. Second of a three-course sequence necessary to complete the Teacher Education Program.
G. Schwanbeck

11.131 Educational Theory and Practice III
______

Undergrad (Spring) HASS Social Sciences
Prereq: 11.130
Units: 3-0-9
______
Students continue their IAP student teaching through mid March. Topics include educational psychology, theories of learning, and using technology and evaluating its effectiveness to enhance student learning. Assignments include readings from educational literature, written reflections on student teaching, presentations on class topics and creating a project that supports student learning at the school where the MIT student is teaching. This is the third of the three-course sequence necessary to complete the Teacher Education Program.
G. Schwanbeck

11.137 Financing Economic Development
______

Undergrad (Fall)
(Subject meets with11.437)
Prereq: None
Units: 4-0-8
Lecture: MW11-12.30 (8-205) Recitation: F1.30 (10-401)
______
Focuses on financing tools and program models to support local economic development. Provides an overview of private capital markets and financing sources to understand capital market imperfections that constrain economic development, business accounting, financial statement analysis, federal economic development programs, and public finance tools. Covers policies and program models, including revolving loan funds, guarantee programs, venture capital funds, bank holding companies, community development loan funds and credit unions, micro enterprise funds, and the Community Reinvestment Act. Students taking graduate version complete additional assignments. Limited to 25.
K. Seidman
Textbooks (Fall 2016)

11.139 The City in Film
______

Undergrad (Spring) HASS Humanities Communication Intensive HASS
(Subject meets with11.239)
Prereq: None
Units: 3-0-9
______
Surveys important developments in urbanism from 1900 to the present, using film as a lens to explore and interpret aspects of the urban experience in the US and abroad. Topics include industrialization, demographics, diversity, the environment, and the relationship between the community and the individual. Films vary from year to year but always include a balance of classics from the history of film, an occasional experimental/avant-garde film, and a number of more recent, mainstream movies. Students taking undergraduate version complete writing assignments that focus on observation, analysis, and the essay, and give an oral presentation. Limited to 18.
E. Glenn

11.140 Urbanization and Development
______

Undergrad (Spring) HASS Social Sciences
(Subject meets with11.480)
Prereq: None
Units: 3-0-9
______
Examines developmental dynamics of rapidly urbanizing locales, with a special focus on the developing world. Case studies from India, China, Mexico, Brazil, and South Africa form the basis for discussion of social, spatial, political and economic changes in cities spurred by the decline of industry, the rise of services, and the proliferation of urban mega projects. Emphasizes the challenges of growing urban inequality, environmental risk, citizen displacement, insufficient housing, and the lack of effective institutions for metropolitan governance. Students taking graduate version complete additional assignments.
Staff

11.142 Geography of the Global Economy
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-0-9
______
Analyzes implications of economic globalization for communities, regions, international businesses and economic development organizations. Uses spatial analysis techniques to model the role of energy resources in shaping international political economy. Investigates key drivers of human, physical, and social capital flows and their roles in modern human settlement systems. Surveys contemporary models of industrialization and places them in geographic context. Connects forces of change with their implications for the distribution of wealth and human well-being.
A. Glasmeier

11.144 Project Appraisal in Developing Countries
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with11.484)
Prereq: Permission of instructor
Units: 3-0-9
______
Covers techniques of financial analysis of investment expenditures, as well as the economic and distributive appraisal of development projects. Critical analysis of these tools in the political economy of international development is discussed. Topics include appraisal's role in the project cycle, planning under conditions of uncertainty, constraints in data quality and the limits of rational analysis, and the coordination of an interdisciplinary appraisal team. Students taking graduate version complete additional assignments. Enrollment limited; preference to majors.
Y. Hong

11.145 International Housing Economics and Finance
______

Undergrad (Spring)
Prereq: 14.01
Units: 3-0-6
Credit cannot also be received for11.355
______
Presents a theory of comparative differences in international housing outcomes. Introduces institutional differences in the ways housing expenditures are financed, and the economic determinants of housing outcomes, such as construction costs, land values, housing quality, and ownership rates. Analyzes the flow of funds to and from the different national housing finance sectors. Develops an understanding of the greater financial and macroeconomic implications of the mortgage credit sector, and how policies affect the ways in which housing asset fluctuations impact national economies. Considers the perspective of investors in international real estate markets and the risks and rewards involved. Draws on lessons from an international comparative approach, and applies them to economic and finance policies at the local, state/provincial, and federal levels within a country of choice. Meets with 11.355 when offered concurrently. Students taking graduate version complete additional assignments.
A. Saiz

11.146 Urbanizing China
______

Undergrad (Fall)
Not offered regularly; consult department
(Subject meets with11.476)
Prereq: None
Units: 2-0-7
URL: http://dusp.mit.edu/subject/fall-2014-11s945
______
Discusses China's daunting urban challenges: congestion and smog, housing affordability, land reform and urban financing, migrants and locals, and social and spatial inequality. Provides examples of laudable achievements and diverse and innovative responses across more than six hundred cities. Presents China's urbanization as the joint result of natural socioeconomic processes and conscious actions by governments, markets, and the public. Presents multidisciplinary approaches and alternative narratives. Examines the intricate interaction between state and market in China's context, yielding a variety of state-market 'cocktails' devised and experimented in different cities in response to local problems, each involving a multilayered projection onto urban space. Students taking graduate version complete additional assignments.
J. Zhao

11.147 Budgeting and Finance for the Public Sector
______

Undergrad (Spring) HASS Social Sciences
(Subject meets with11.487)
Prereq: Permission of instructor
Units: 3-0-9
______
Examines globally relevant challenges of adequately and effectively attending to public sector responsibilities for basic services with limited resources. Particular attention to the contexts of fiscal crises and rapid population growth, as well as shrinkage, through an introduction to methods and processes of budgeting, accounting, and financial mobilization. Case studies and practice exercises explore revenue strategies, demonstrate fiscal analytical competencies, and familiarize students with pioneering examples of promising budget and accounting processes and innovative funding mobilization via taxation, capital markets, and other mechanisms (e.g., land-value capture). Students taking graduate version explore the subject in greater depth.
G. Carolini

11.148 Environmental Justice: Law and Policy
(New)
______

Not offered academic year 2017-2018Undergrad (Fall)
(Subject meets with11.368)
Prereq: None
Units: 3-0-9
Lecture: M2-5 (9-217)
______
Introduces frameworks for analyzing and addressing inequalities in the distribution of environmental benefits and burdens. Explores the foundations and principles of the environmental justice movement from the perspectives of social science, public policy, and law. Applies environmental justice principles to contemporary issues in urban policy and planning. Students taking graduate version complete additional assignments.
J. Steil
No textbook information available

11.150[J] Metropolis: A Comparative History of New York City
______

Undergrad (Fall) HASS Humanities
(Same subject as21H.220[J])
Prereq: None
Units: 3-0-9
Lecture: W EVE (7-10 PM) (2-135)
______
Examines the evolution of New York City from 1607 to the present. Readings focus on the city's social and physical histories. Discussions compare New York's development to patterns in other cities.
C. Wilder
Textbooks (Fall 2016)

11.151[J] Youth Political Participation
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Humanities
(Same subject asSTS.080[J])
Prereq: None
Units: 3-0-9
______
Surveys youth political participation in the US since the early 1800s. Investigates trends in youth political activism during specific historical periods, as well as what difference youth media production and technology use (e.g., radio, music, automobiles, ready-made clothing) made in determining the course of events. Explores what is truly new about "new media" and reviews lessons from history for present-day activists based on patterns of past failure and success. Some mandatory field trips may occur during class time. Limited to 40.
J. S. Light

11.152[J] The Ghetto: From Venice to Harlem
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject as21H.385[J])
Prereq: None
Units: 2-0-10
______
Provides an in-depth look at a modern institution of oppression: the ghetto. Uses literature to examine ghettoization over time and across a wide geographical area, from Jews in Medieval Europe to African-Americans and Latinos in the 20th-century United States. Also explores segregation and poverty in the urban "Third World."
C. Wilder

11.153[J] Shanghai and China's Modernization
______

Undergrad (Spring) HASS Humanities
(Same subject as21H.351[J])
Prereq: None
Units: 2-0-10
______
Considers the history and function of Shanghai, from 1840 to the present, and its rise from provincial backwater to international metropolis. Examines its role as a primary point of economic, political, and social contact between China and the world, and the strong grip Shanghai holds on both the Chinese and foreign imagination. Students discuss the major events and figures of Shanghai, critique the classic historiography, and complete an independent project on Shanghai history.
C. Leighton

11.161[J] Energy Decisions, Markets, and Policies
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject as14.43[J],15.031[J],17.397[J],21A.415[J])
Prereq: 14.01, 15.0111, or permission of instructor
Units: 4-0-8
______
Structured around choices and constraints regarding sources and uses of energy by households, firms, and governments, introduces managerial, economic, political, social and cultural frameworks for describing and explaining behavior at various levels of aggregation. Includes examples of cost-benefit, organizational and institutional analyses of energy generation, distribution, and consumption. Topics include the role of markets and prices; financial analysis of energy-related investments; institutional path dependence; economic and political determinants of government regulation and the impact of regulation on decisions; and other forms of government action and social norms regarding desired behavior and opportunities for businesses and consumers, including feedback into the political/regulatory system. Examples drawn from a wide range of countries and settings.
C. Warshaw

11.162 Politics of Energy and the Environment
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-0-9
______
Focuses on the politics of making local, state, national and international decisions on energy and the environment. Topics include implementing energy efficiency measures, siting nuclear and alternative energy plants, promoting oil and gas development offshore and in wilderness, adapting to climate change, handling toxic waste, protecting endangered species, and conserving water. Case studies include Cape Wind, disputes over oil and gas exploration in the Arctic, the response to Hurricane Katrina, and efforts to craft and comply with the greenhouse gas emissions limits.
Staff

11.163[J] Law and Society
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject as17.249[J],21A.455[J])
(Subject meets with21A.459)
Prereq: None
Units: 3-0-9
______
Studies legal reasoning, types of law and legal systems, and relationship of law to social class and social change. Emphasizes the profession and practice of law, including legal education, stratification within the bar, and the politics of legal services. Investigates emerging issues in the relationship between institutions of law and science.
S. Silbey

11.164[J] Human Rights at Home and Abroad
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject as17.391[J])
(Subject meets with11.497)
Prereq: Permission of instructor
Units: 3-0-9
______
Provides a rigorous and critical introduction to the history, foundation, structure, and operation of the human rights movement. Focuses on key ideas, actors, methods and sources, and critically evaluates the field. Addresses current debates in human rights, including the relationship with security, democracy, development and globalization, urbanization, equality (in housing and other economic and social rights; women's rights; ethnic, religious and racial discrimination; and policing/conflict), post-conflict rebuilding and transitional justice, and technology-related issues. Prior coursework, work experience, or community service that demonstrates familiarity with global affairs or engagement with ethics and social justice issues, preferred. Students taking graduate version expected to write a research paper.
B. Rajagopal

11.165 Urban Energy Systems and Policy
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Subject meets with1.286[J],11.477[J])
Prereq: 14.01 or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Examines efforts in developing and advanced nations and regions. Examines key issues in the current and future development of urban energy systems, such as technology, use, behavior, regulation, climate change, and lack of access or energy poverty. Case studies on a diverse sampling of cities explore how prospective technologies and policies can be implemented. Includes intensive group research projects, discussion, and debate. Students taking the graduate version complete additional assignments.
D. Hsu

11.166 Law, Social Movements, and Public Policy: Comparative and International Experience
______

Undergrad (Spring) HASS Social Sciences
(Subject meets with11.496)
Prereq: Permission of instructor
Units: 3-0-9
______
Studies the interaction between law, courts, and social movements in shaping domestic and global public policy. Examines how groups mobilize to use law to affect change and why they succeed and fail. Case studies explore the interplay between law, social movements, and public policy in current issues, such as gender, race, labor, trade, climate change/environment, and LGBTQ rights. Introduces theories of public policy, social movements, law and society, and transnational studies. Students taking graduate version complete additional assignments. Limited to 15.
B. Rajagopal

11.183 Property and Land Use Law for Planners
______

Not offered academic year 2017-2018Undergrad (Fall)
(Subject meets with11.493)
Prereq: None
Units: 3-0-9
Lecture: W2-5 (9-450B)
______
Examines legal and institutional arrangements for the establishment, transfer, and control over property under American and selected comparative systems, including India and South Africa. Focuses on key issues of property and land use law regarding planning and economic development. Emphasizes just and efficient resource use; institutional, entitlement and social relational approaches to property; distributional and other social aspects; and the relationship between property, culture, and democracy.
B. Rajagopal
No textbook information available

Laboratories

11.188 Urban Planning and Social Science Laboratory
______

Undergrad (Spring) Institute Lab
Prereq: None
Units: 3-3-6
Credit cannot also be received for11.205
______
An introduction to the research and empirical analysis of urban planning issues using geographic information systems. Extensive hands-on exercises provide experience with various techniques in spatial analysis and querying databases. Includes a small project on an urban planning problem involving the selection of appropriate methods, the use of primary and secondary data, computer-based modeling, and spatial analysis. Requires some computing experience.
J. Ferreira

Tutorials, Fieldwork, and Internships

11.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually

11.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Undergraduate research opportunities in Urban Studies and Planning. For further information, consult the Departmental Coordinators.
E. Klopfer
Textbooks arranged individually

11.THT[J] Thesis Research Design Seminar
______

Undergrad (Fall) Can be repeated for credit
(Same subject as4.THT[J])
Prereq: None
Units: 3-0-9
Lecture: F12-3 (9-217)
______
Designed for students writing a thesis in Urban Studies and Planning or Architecture. Develop research topics, review relevant research and scholarship, frame research questions and arguments, choose an appropriate methodology for analysis, and draft introductory and methodology sections.
C. Abbanat
No required or recommended textbooks

11.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 11.THT
Units arranged
TBA.
______
Program of research leading to the writing of an SB thesis. To be arranged by the student under approved supervision.
Staff
Textbooks arranged individually

11.189-11.190 Urban Fieldwork
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
11.189: TBA.
11.190: TBA.
______
Practical application of city and regional planning techniques to towns, cities, and regions, including problems of replanning, redevelopment, and renewal of existing communities. Includes internships, under staff supervision, in municipal and state agencies and departments.
Staff
11.189: No required or recommended textbooks
11.190: No required or recommended textbooks

11.191-11.192 Independent Study
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
11.191: TBA.
11.192: TBA.
______
For undergraduates wishing to pursue further study in specialized areas of urban studies or city and regional planning not covered in regular subjects.
Staff
11.191: No required or recommended textbooks
11.192: No required or recommended textbooks

11.193-11.194 Supervised Readings
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
11.193: TBA.
11.194: TBA.
______
Reading and discussion of topics in urban studies and planning.
Staff
11.193: No required or recommended textbooks
11.194: No required or recommended textbooks

11.S195 Special Subject: Urban Studies and Planning
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
11.S195: URL: https://dusp.mit.edu/subject/fall-2016-11s195
11.S195: Lecture: TR1-2.30 (56-154)
Subject Cancelled 11.S196 Cancelled
Subject Cancelled 11.S197 Cancelled
Subject Cancelled 11.S198 Cancelled
Subject Cancelled 11.S199 Cancelled
______
11.S195: No textbook information available

11.S196-11.S199 Special Subject: Urban Studies and Planning
______

Undergrad (Spring) Can be repeated for credit
Prereq: None
Units arranged
11.S195: URL: https://dusp.mit.edu/subject/fall-2016-11s195
11.S195: Lecture: TR1-2.30 (56-154)
Subject Cancelled 11.S196 Cancelled
Subject Cancelled 11.S197 Cancelled
Subject Cancelled 11.S198 Cancelled
Subject Cancelled 11.S199 Cancelled
______
For undergraduates wishing to pursue further study or fieldwork in specialized areas of urban studies or city and regional planning not covered in regular subjects of instruction. 11.S198 is graded P/D/F.
Staff
11.S195: No textbook information available


left arrow|Undergraduate: 11.00-11.199
plus UROP, ThU, ThT
|Graduate: 11.20-11.299|Graduate: 11.30-11.999 plus ThG|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 11: Urban Studies and Planning
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Course 11: Urban Studies and Planning
Fall 2016


Master's Core Subjects

11.201 Gateway: Planning Action
______

Graduate (Fall)
Prereq: None
Units: 4-1-7
Lecture: MW11-12.30 (9-354) Recitation: F12-1.30 (9-450A) or F1.30-3 (9-450A, 9-450B) or F3-4.30 (9-450A, 9-451)
______
Introduces the profession of urban and regional planning. Emphasizes the key sensibilities necessary for effective planning practice as well as professional writing and oral communication skills.
J. Buckley
No textbook information available

11.202 Planning Economics
______

Graduate (Fall); partial term
Prereq: 11.203
Units: 2-0-2
Begins Oct 24. Lecture: TR11-12.30 (9-354) Recitation: R EVE (5-6.30 PM) (9-450A) or R3.30-5 (9-450B) or F10.30-12 (9-451)
______
Introduces applications of microeconomic theory to planning problems including urban form and structure, government's role in urban settings and problems of housing finance.
A. Saiz
No textbook information available

11.203 Microeconomics
______

Graduate (Fall); partial term
Prereq: None
Units: 3-0-5
Ends Oct 21. Lecture: TR11-12.30 (9-354) Recitation: R EVE (5-6.30 PM) (9-450A) or R3.30-5 (9-450B) or F10.30-12 (9-451)
______
Introduces basic economic analysis for planning students including the functioning of markets, the allocation of scarce resources among competing uses, profit maximizing behavior in different market structures. Course illustrates theory with contemporary economic issues.
A. Saiz
Textbooks (Fall 2016)

11.205 Introduction to Spatial Analysis
______

Graduate (Fall, Spring); partial term
Prereq: None
Units: 2-2-2
Credit cannot also be received for11.188
Ends Oct 28. Lecture: MW2.30-4 (9-354) Lab: M EVE (5-7 PM) (W31-301) or T EVE (5-7 PM) (W31-301) or W EVE (5-7 PM) (W31-301) or R EVE (5-7 PM) (W31-301)
______
Practical introduction to spatial analysis and geographic information systems (GIS). Examines how geography is represented digitally and how nonrandom distributions of phenomena as diverse as poverty and scenic resources can be better understood by examining their spatial characteristics. Limited enrollment; preference to first-year MCP students.
Fall:S. Williams
Spring:J. Ferreira
No textbook information available

11.206 Poverty and Economic Security
(New)
______

Not offered academic year 2017-2018Graduate (Fall)
(Subject meets with11.006)
Prereq: None
Units: 3-0-9
Lecture: TR9.30-11 (9-255)
______
Explores the evolution of poverty and economic security in the US within a global context. Examines the impacts of recent economic restructuring and globalization. Reviews current debates about the fate of the middle class, sources of increasing inequality, and approaches to advancing economic opportunity and security. Students taking graduate version complete additional assignments.
A. Glasmeier
No textbook information available

11.220 Quantitative Reasoning and Statistical Methods for Planning I
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 4-2-6
______
Develops logical, empirically based arguments using statistical techniques and analytic methods. Covers elementary statistics, probability, and other types of quantitative reasoning useful for description, estimation, comparison, and explanation. Emphasizes the use and limitations of analytical techniques in planning practice. Restricted to MCP students.
J. Zhao

Department-wide Subjects

11.225 Argumentation and Communication
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units: 2-0-4
______
A writing practicum associated with 11.201 that focuses on helping students write and present their ideas in cogent, persuasive arguments and other analytical frameworks. Reading and writing assignments and other exercises stress the connections between clear thinking, critical reading, and effective writing.
C. Abbanat

11.229 Advanced Writing Seminar
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: None
Units: 2-0-7
______
Focuses on writing and speaking skills. Students bring their writing from other classes to the workshop to practice reviewing and rewriting skills and make several oral presentations. Different types of writing including proposals, memos, thesis, press releases, and writing sound bites for the media.
C. Abbanat

11.233 Research Design for Policy Analysis and Planning
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: T9.30-12.30 (9-217)
______
Develops skills in research design for policy analysis and planning. Emphasizes the logic of the research process and its constituent elements. Topics include philosophy of science, question formulation, hypothesis generation and theory construction, data collection techniques (e.g. experimental, survey, interview), ethical issues in research, and research proposal preparation. Limited to doctoral students in Course 11.
G. Carolini
No textbook information available

11.234 Making Sense: Qualitative Methods for Designers and Planners
______

Graduate (Spring)
Prereq: None
Units: 3-3-6
______
Surveys uses of qualitative methods in urban design and planning research and practice. Topics include observing environments, physical traces, and environmental behavior; asking questions; focused interviews; standardized questionnaires; use of written archival materials; use of visual materials, including photographs, new media, and maps; case studies; and comparative methods. Emphasizes use of each of these skills to collect and make sense of qualitative data in community and institutional settings.
Staff

11.236 Theory of Participatory Action Research (PAR)
______

Graduate (Fall); partial term
Prereq: None
Units: 2-0-4
URL: http://dusp.mit.edu/subject/fall-2014-11s944
Ends Oct 21. Lecture: TR EVE (5-6.30 PM) (9-451)
______
Introduces the theory of participatory action research (PAR) and competing ideas about the uses of social research to promote social change. Focuses on the epistemological foundation for and knowledge generation in action research, as well as on approaches to co-producing research that requires engagement of the subjects, communities, or organizations that are being studied in the design, implementation and interpretation of applied social research. Explores the ethical obligations of outsiders along with rights and responsibilities of insiders in the research findings. Emphasizes recent scholarship, including arguments for and against phronetic social science.
L. Susskind, D. Cunningham
Textbooks (Fall 2016)

11.237 Practice of Participatory Action Research (PAR)
______

Graduate (Spring); partial term
Prereq: 11.236 or permission of instructor
Units: 2-0-4
______
Introduces the techniques of participatory action research (PAR) and the practice of case study research. Presents competing ideas about context-independent vs. context-dependent knowledge, arguments for and against generating theory on the basis of a single case, and problems of verification in PAR (i.e., disconfirming the researchers preconceptions). Focuses on actual cases in which PAR-like methods have been used with greater or lesser success. Integrates interactions with representatives of communities, organizations, and individuals who have been the focus of PAR. Analyzes techniques for co-designing and co-conducting all aspects of applied social research.
D. Cunningham

11.238[J] Ethics of Intervention
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as21A.409[J])
Prereq: Permission of instructor
Units: 3-0-9
______
An historical and cross-cultural study of the logics and practices of intervention: the ways that individuals, institutions, and governments identify conditions of need or states of emergency within and across borders that require a response. Examines when a response is viewed as obligatory, when is it deemed unnecessary, and by whom; when the intercession is considered fulfilled; and the rationales or assumptions that are employed in assessing interventions. Theories of the state, globalization, and humanitarianism; power, policy, and institutions; gender, race, and ethnicity; and law, ethics, and morality are examined.
E. C. James

11.239 The City in Film
______

Graduate (Spring)
(Subject meets with11.139)
Prereq: Permission of instructor
Units: 2-2-5
______
Surveys important developments in urbanism from 1900 to the present, using film as a lens to explore and interpret aspects of the urban experience in the US and abroad. Topics include industrialization, demographics, diversity, the environment, and the relationship between the community and the individual. Films vary from year to year but always include a balance of classics from the history of film, an occasional experimental/avant-garde film, and a number of more recent, mainstream movies. Students taking undergraduate version complete writing assignments that focus on observation, analysis, and the essay, and give an oral presentation.
E. Glenn

11.250 Transportation Research Design
(New)
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of Instructor
Units: 2-0-1 [P/D/F]
Lecture: F12-1.30 (9-450B)
______
Seminar dissects ten transportation studies from head to toe to illustrate how research ideas are initiated, framed, analyzed, evidenced, written, presented, criticized, revised, extended, and published, quoted and applied. Students design and execute their own transportation research. Limited to 20.
J. Zhao
No required or recommended textbooks

11.252[J] Design and Development of Games for Learning
______

Graduate (Spring)
(Same subject asCMS.863[J])
(Subject meets with11.127[J],CMS.590[J])
Prereq: None
Units: 3-6-3
______
Immerses students in the process of building and testing their own digital and board games in order to better understand how we learn from games. Explores the design and use of games in the classroom in addition to research and development issues associated with computer-based (desktop and handheld) and non-computer-based media. In developing their own games, students examine what and how people learn from them (including field testing of products), as well as how games can be implemented in educational settings. All levels of computer experience welcome. Students taking graduate version complete additional assignments.
E. Klopfer

11.255 Negotiation and Dispute Resolution in the Public Sector
______

Graduate (Spring)
Prereq: None
Units: 4-0-8
______
Investigates social conflict and distributional disputes in the public sector. While theoretical aspects of conflict and consensus building are considered, focus is on the practice of negotiation and dispute resolution. Comparisons between unassisted and assisted negotiation are reviewed along with the techniques of facilitation and mediation.
L. Susskind


left arrow|Undergraduate: 11.00-11.199
plus UROP, ThU, ThT
|Graduate: 11.20-11.299|Graduate: 11.30-11.999 plus ThG|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 11: Urban Studies and Planning
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  MIT Course Picker | MIT Course Planner     
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Course 11: Urban Studies and Planning
Fall 2016


Program Group Subjects

11.301[J] Introduction to Urban Design and Development
______

Graduate (Fall)
(Same subject as4.252[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR9.30-11 (9-354)
______
Examines both the structure of cities and ways they can be changed. Includes historical forces that have produced cities, models of urban analysis, contemporary theories of urban design, implementation strategies. Core lectures supplemented by discussion sessions focusing on student work and field trips. Guest speakers present cases involving current projects illustrating the scope and methods of urban design practice.
D. Frenchman
No required or recommended textbooks

11.302[J] Urban Design Politics
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as4.253[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Examines ways urban design contributes to distribution of political power and resources in cities. Investigates the nature of relations between built form and political purposes through close study of a wide variety of situations where public sector design commissions and planning processes have been clearly motivated by political pressures. Lectures and discussions focus on specific case studies of 20th-century government-sponsored designs carried out under diverse regimes in the US, Europe, and elsewhere.
L. Vale

11.303[J] Real Estate Development Studio: Complex Urban Projects
______

Graduate (Spring)
(Same subject as4.254[J])
Prereq: Permission of instructor
Units: 6-0-12
______
Focuses on the synthesis of projects for the real estate development industry, including the integration of physical design and programming with finance and marketing. Interdisciplinary student teams analyze how to maximize value in large-scale, mixed use projects in the process of preparing professional development proposals, involving sites in US cities and internationally. Reviews emerging real estate products and innovative developments to provide a foundation for studio work. Two major projects are interspersed with lectures, field trips, and short sketch exercises. Integrates skills and knowledge in the MSRED program; also open to other students interested in real estate development.
D. Frenchman, P. Roth

11.304[J] Site and Environmental Systems Planning
______

Graduate (Spring)
(Same subject as4.255[J])
Prereq: Permission of instructor
Units: 6-0-9
______
Introduces a range of practical approaches involved in evaluating and planning sites within the context of natural and cultural systems. Develops the knowledge and skills to analyze and plan a site for development through exercises and an urban design project. Topics include land inventory, urban form, spatial organization of uses, parcelization, design of roadways, grading, utility systems, off-site impacts, and landscape architecture.
M. A. Ocampo

11.307[J] Beijing Urban Design Studio
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as4.173[J])
Prereq: Permission of instructor
Units: 0-18-0
TBA.
______
Design studio that includes architects and city planners working in teams on a contemporary development project of importance in China. Students analyze conditions, explore alternatives, and synthesize architecture, city design, and implementation plans. Lectures and brief study tours expose students to history and contemporary issues of urbanism in China. Offered every other summer in residence at Tsinghua University, Beijing, involving students and faculty from both schools. Limited to 10.
D. Frenchman, C. Zegras
No textbook information available

11.308[J] Ecological Urbanism Seminar
______

Graduate (Fall)
(Same subject as4.213[J])
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4213
Lecture: M2-5 (10-401)
______
Examines the urban environment as a natural phenomenon, human habitat, medium of expression, and forum for action. Subject has two related, major themes: how ideas of nature influence the way cities are perceived, designed, built, and managed; and how natural processes and urban form interact and the consequences of these for human health safety and welfare. Enrollment limited.
A. Spirn
Textbooks (Fall 2016)

11.309[J] Sensing Place: Photography as Inquiry
______

Graduate (Fall)
(Same subject as4.215[J])
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4215
Lecture: W EVE (2-6 PM) (10-485)
______
Explores photography as a disciplined way of seeing, of investigating urban landscapes and expressing ideas. Readings, observations, and photographs form the basis of discussions on light, detail, place, poetics, narrative, and how photography can inform design and planning. Enrollment limited.
A. Spirn
Textbooks (Fall 2016)

11.312 Engaging Community: Models and Methods for Designers and Planners
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Reviews a range of models for engaging communities, from a client-consultant relationship to advocacy, community organizing, consensus building, capacity building, and knowledge building. Explores the ways these different models have been used in design and planning practice and community building.
C. McDowell

11.313 Advanced Research Workshop in Landscape and Urbanism
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of Instructor
Units: 3-0-9
______
In-depth research workshop on pressing environmental design issue of our time, includes discussion and practices of various Landscape-based disciplines used to generate design-based solutions and landscape infrastructural responses to physical urban entropy and decline. Specific focus is adjusted each year.
A. Berger

11.314[J] Water, Landscape and Urban Design
______

Not offered academic year 2017-2018Graduate (Spring) Can be repeated for credit
(Same subject as4.214[J])
Prereq: Permission of instructor
Units: 3-3-6
______
Workshop surveys how water affects the design of buildings, landscapes and cities in aesthetic, functional and symbolic ways. Combines the systematic study of water issues with urban design projects in South Asia and the US. Covers topics such as rainwater harvesting, water use efficiency, wastewater reuse, stormwater management, floodplain design, constructed wetlands, and waterfront development. Students work together to integrate these design concepts at the site, urban, and international scales. Limited to 15.
J. Wescoat

11.315[J] Disaster Resilient Design
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as4.217[J])
Prereq: None
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Seminar examines the linkages between natural hazards and environmental design. Engages theoretical debates about landscapes of risk, vulnerability, and resilience. Participants generate proposals for disaster resilience through combinations of retrofit, reconstruction, resettlement, commemorative, and anticipatory design. Methods include rapid bibliographic search, risk analysis, landscape synthesis, and comparative international methods. Projects vary and may focus on current crises or involve collaboration with the Aga Khan Development Network and other humanitarian organizations. Limited to 15.
J. Wescoat

11.316[J] Landscape and Urban Heritage Conservation
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
(Same subject as4.216[J])
Prereq: Permission of instructor
Units: 3-3-6
______
Focuses on cultural landscape history, theory, and heritage issues and projects in the Indo-Islamic realm. Landscape and urban heritage inquiry go beyond monuments to encompass sites, cites, and regions. Combines the study of conservation theory and practice with an exploration of active urban landscape planning and design projects. Limited to 15.
J. Wescoat

11.318 Senseable Cities
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Studies how ubiquitous and real-time information technology can help us to understand and improve cities and regions. Explores the impact of integrating real-time information technology into the built environment. Introduces theoretical foundations of ubiquitous computing. Provides technical tools for tactile development of small-scale projects. Limited to 24.
C. Ratti

11.320 Digital City Design Workshop
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Students develop proposals, at the city and neighborhood scales, that integrate urban design, planning, and digital technology. Aims to create more efficient, responsive, and livable urban places and systems that combine physical form with digital media, sensing, communications, and data analysis. Students conduct field research, build project briefs, and deliver designs or prototypes, while supported by lectures, case studies, and involvement from experts and representatives of subject cities. Limited to 12.
D. Frenchman, C. Ratti

11.328[J] Urban Design Skills: Observing, Interpreting, and Representing the City
______

Graduate (Fall)
(Same subject as4.240[J])
Prereq: None
Units: 4-2-9
URL: http://architecture.mit.edu/subject/fall-2016-4240
Lecture: F9-1 (10-485) Recitation: W EVE (6-9 PM) (10-485)
______
Introduces methods of recording, evaluating, and representing the urban environment. Through visual observation, field analysis, measurements, interviews, and other means, students draw on their senses and develop their ability to deduce, conclude, question, and test conclusions about how the environment is used and valued. Using representational tools such as drawing, photographing, computer modeling and desktop publishing, students communicate what they observe along with their impressions and design ideas. Intended as a foundation for future studio work in urban design. Includes design-based projects.
E. Ben-Joseph
No required or recommended textbooks

11.330[J] The Making of Cities
______

Graduate (Spring)
(Same subject as4.241[J])
(Subject meets with4.251)
Prereq: 4.252 or 11.001
Units arranged
______
Examines the complex development of cities through history by tracing a diachronic accumulation of forms and spaces in specific cities, and showing how significant ideas were made manifest across distinct geographies and cultures. Emphasizes how economic, spiritual, political, geographic and technological forces have simultaneously shaped and, in turn, been influenced by the city. Additional work required of students taking graduate version.
L. Jacobi, R. Segal

11.332[J] Urban Design Studio
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as4.163[J])
Prereq: 4.162 or permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4163
Design: TR EVE (1-6 PM) (STUDIO)
______
The design of urban environments. Strategies for change in large areas of cities, to be developed over time, involving different actors. Fitting forms into natural, man-made, historical, and cultural contexts; enabling desirable activity patterns; conceptualizing built form; providing infrastructure and service systems; guiding the sensory character of development. Involves architecture and planning students in joint work; requires individual designs or design and planning guidelines.
M. Mazereeuw, A. Berger, F. Masoud
No textbook information available

11.333[J] Urban Design Seminar: Perspectives on Contemporary Practice
______

Graduate (Spring)
(Same subject as4.244[J])
Prereq: None
Units: 2-0-7
______
Examines innovations in urban design practice occurring through the work of leading practitioners in the fields of architecture, landscape architecture, and urban planning. Features lectures by major national and global practitioners in urban design. Projects and topics vary based on term and speakers but may cover architectural urbanism, landscape and ecology, arts and culture, urban design regulation and planning agencies, and citywide and regional design. Focuses on analysis and synthesis of themes discussed in presentations and discussions.
Staff

11.334[J] Advanced Seminar in Landscape and Urbanism
______

Graduate (Spring)
(Same subject as4.264[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Explores theories, practices, and emerging trends in the fields of landscape architecture and urbanism, such as systemic design, landscape urbanism, engineered nature, drosscapes, urban biodiversity, urban mobility, megaregions, and urban agriculture. Lectures, readings, and guest speakers present a wide array of multi-disciplinary topics, including current works from P-REX lab. Students conduct independent and group research that is future-oriented.
A. Berger

11.337[J] Urban Design Ideals and Action
______

Graduate (Spring)
(Same subject as4.247[J])
Prereq: 11.301 or permission of instructor
Units: 2-0-7
______
Examines the relationship between urban design ideals, urban design action, and the built environment through readings, discussions, presentations, and papers. Analyzes the diverse design ideals that influence cities and settlements, and investigates how urban designers use them to shape urban form. Provides a critical understanding of the diverse formal methods used to intervene creatively in both developed and developing contexts, especially pluralistic and informal built environments.
B. Ryan

11.338 Urban Design Studio
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 11.328
Units: 0-12-9
______
Examines the rehabilitation and re-imagination of a city. Analyzes the city at three scales: citywide, neighborhood, and individual dwellings. Aims to shape innovative design solutions, enhance social amenity, and improve economic equity through strategic and creative geographical, urban design and architectural thinking. Intended for students with backgrounds in architecture, community development, and physical planning. Limited to 12 via application and lottery.
B. Ryan

11.339 Downtown
______

Graduate (Spring)
(Subject meets with11.026[J],21H.321[J])
Prereq: None
Units: 2-0-7
______
Seminar on downtown in US cities from the late 19th century to the late 20th. Emphasis on downtown as an idea, place, and cluster of interests, on the changing character of downtown, and on recent efforts to rebuild it. Topics considered include subways, skyscrapers, highways, urban renewal, and retail centers. Focus on readings, discussions, and individual research projects. Students taking graduate version complete additional assignments.
R. M. Fogelson

11.342[J] Globalization and the Built Environment
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as1.463[J])
Prereq: Permission of instructor
Units: 2-0-4
______
Addresses the importance and pervasiveness of globalization in Architecture, Engineering and Construction Companies (AEC Firms). Covers strategies for a presence in the global market and the importance of the global financial market in project financing, with a primary focus on infrastructure. Includes discussion of innovative approaches to marketing, partnering, risk management, finance, specialized delivery systems, and privatization.
F. Moavenzadeh, D. Wolff

11.344[J] Innovative Project Delivery in the Public and Private Sectors
______

Graduate (Spring); first half of term
(Same subject as1.472[J])
Prereq: Permission of instructor
Units: 2-0-4
______
Develops a strong strategic understanding of how best to deliver various types of projects in the built environment. Examines the compatibility of various project delivery methods, consisting of organizations, contracts, and award methods, with certain types of projects and owners. Six methods examined: traditional general contracting; construction management; multiple primes; design-build; turnkey; and build-operate-transfer. Includes lectures, case studies, guest speakers, and a team project to analyze a case example.
C. M. Gordon

11.345[J] Entrepreneurship in Construction and Real Estate Development
______

Graduate (Fall); second half of term
(Same subject as1.462[J])
Prereq: Permission of instructor
Units: 2-0-4
Begins Oct 24. Lecture: R3-5.30 (9-354)
______
Develops skills necessary to incubate concepts for new real estate/built environment ventures and to evolve those ideas into viable startup ventures. Addresses the progression of an idea, from inception to opportunity to sustainable business. Students develop a business plan. Guest lecturers share their entrepreneurial paths and relevant experience. Explores the role of real estate developers in developing/emerging markets, with a focus on solving social development challenges, innovating new development strategies/products, and generating triple bottom-line returns with development projects.
J. F. Kennedy
Textbooks (Fall 2016)

11.351 Real Estate Ventures I: Negotiating Development-Phase Agreements
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Lecture: R EVE (6-9 PM) (9-354)
______
Focuses on key business and legal issues within the principal agreements used to control, entitle, capitalize, and construct a mixed-use real estate development. Through the lens of the real estate developer and its counter-parties, students identify, discuss, and negotiate the most important business issues in right of entry, purchase and sale, development, and joint-venture agreements, as well as a construction contract and construction loan agreement. Students work closely with attorneys who specialize in the construction of such agreements and with students from area law schools and Columbia University. Enrollment limited; preference to MSRED students. No listeners.
W. T. McGrath
No required or recommended textbooks

11.352 Real Estate Ventures II: Negotiating Leases, Financings, and Restructurings
______

Graduate (Spring)
Prereq: 11.351 or permission of instructor
Units: 3-0-9
______
Focuses on the key business and legal issues within the principal agreements used to lease, finance, and restructure a real estate venture. Through the lens of the real estate developer and its counter-parties, students identify, discuss and negotiate the most important business issues in office and retail leases, and permanent loan, mezzanine loan, intercreditor, standstill/forbearance, and loan modification (workout) agreements. In doing so, students work closely with attorneys who specialize in the construction of such agreements. Also touches on single-asset real estate bankruptcy and the federal income tax consequences of debt restructuring. Enrollment limited; preference to MSRED students.
W. T. McGrath

11.353[J] Securitization of Mortgages and Other Assets
______

Graduate (Spring)
(Same subject as15.429[J])
Prereq: 15.426, 15.401, or permission of instructor
Units: 3-0-6
______
Investigates the economics and finance of securitization, a practice that allows illiquid assets to be transformed into more liquid securities. Considers the basic mechanics of structuring deals for various asset-backed securities. Investigates the pricing of pooled assets, using Monte Carlo and other option pricing techniques, as well as various trading strategies used in these markets.
W. Torous

11.354 Real Estate Products Seminar
______

Graduate (Fall)
Prereq: None
Units: 3-0-3
Lecture: T1-2.30 (9-354)
______
Examines the fundamentals of real estate development products, including residential, hotel, office, research and development/lab, retail, and industrial uses. Includes faculty lectures, guest presentations, and field trips to local case study projects. Prepares MSRED candidates for the spring Real Estate Development Studio.
J. Cookke
No textbook information available

11.355 International Housing Economics and Finance
______

Graduate (Spring)
Prereq: 11.202, 11.203, 14.01 or permission of instructor
Units: 3-0-6
Credit cannot also be received for11.145
______
Presents a theory of comparative differences in international housing outcomes. Introduces institutional differences in the ways housing expenditures are financed, and the economic determinants of housing outcomes, such as construction costs, land values, housing quality, and ownership rates. Analyzes the flow of funds to and from the different national housing finance sectors. Develops an understanding of the greater financial and macroeconomic implications of the mortgage credit sector, and how policies affect the ways in which housing asset fluctuations impact national economies. Considers the perspective of investors in international real estate markets and the risks and rewards involved. Draws on lessons from an international comparative approach, and applies them to economic and finance policies at the local, state/provincial, and federal levels within a country of choice. Meets with 11.145 when offered concurrently. Students taking graduate version complete additional assignments.
A. Saiz

11.360 Community Growth and Land Use Planning
______

Graduate (Fall)
Prereq: Permission of Instructor
Units: 3-0-9
Lecture: TR2.30-4 (10-401)
______
Practicum workshop on strategies of planning and control for growth and land use, chiefly at the municipal level. Growth and its local consequences; land use planning approaches; implementation tools including innovative zoning and regulatory techniques, physical design, and natural systems integration. Semester-long projects arranged with student teams serving municipal clients. Preference to MCP second year students.
T. S. Szold
No required or recommended textbooks

11.364 International Environmental Treaties and Their Implementation
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 11.601, 11.255, or permission of instructor
Units: 3-0-6
______
Examines the history and dynamics of international environmental treaty-making, or what is called environmental diplomacy. Emphasis is on climate change and other atmospheric, marine resource, global waste management and sustainability-related treaties and the problems of implementing them. Reviews the legal, economic, and political dynamics of managing shared resources, involving civil society on a global basis, and enforcing transboundary agreements. Focuses especially on principles from international relations, international law, environmental management and negotiation theory as they relate to common-pool resource management.
L. Susskind

11.367 The Law and Politics of Land Use
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Analysis of local and state power to regulate land use and development. Particular emphasis on the evolution of planning and zoning regulations, and the perceived narrowing of the relationship between public improvements requirements and development impact. The ability of regulatory bodies to impose environmental performance standards and limit development activity is explored in relation to recent Supreme Court and State SJC decisions. Development decisions rendered by public agencies are reviewed, critiqued, and discussed.
T. S. Szold

11.368 Environmental Justice: Law and Policy
______

Not offered academic year 2017-2018Graduate (Fall)
(Subject meets with11.148)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: M2-5 (9-217)
______
Introduces frameworks for analyzing and addressing inequalities in the distribution of environmental benefits and burdens. Explores the foundations and principles of the environmental justice movement from the perspectives of social science, public policy, and law. Applies environmental justice principles to contemporary issues in urban policy and planning.
J. Steil
Textbooks (Fall 2016)

11.371[J] Sustainable Energy
______

Graduate (Fall)
(Same subject as1.818[J],2.65[J],10.391[J],22.811[J])
(Subject meets with2.650[J],10.291[J],22.081[J])
Prereq: Permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/10.391J/www/
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various energy technologies in each fuel cycle stage for fossil (oil, gas, synthetic), nuclear (fission and fusion) and renewable (solar, biomass, wind, hydro, and geothermal) energy types, along with storage, transmission, and conservation issues. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments.
M. W. Golay
Textbooks (Fall 2016)

11.373[J] Science, Politics, and Environmental Policy
______

Graduate (Fall)
(Same subject as12.885[J])
(Subject meets with12.385)
Prereq: Permission of instructor
Units: 3-0-6
Lecture: M EVE (3-6 PM) (54-1623)
______
Examines the role of science in US and international environmental policymaking. Surveys the methods by which scientists learn about the natural world; the treatment of science by experts, advocates, the media, and the public and the way science is used in legislative, administrative and judicial decision making. Through lectures, group discussions, and written essays, students develop a critical understanding of the role of science in environmental policy. Potential case studies include fisheries management, ozone depletion, global warming, smog, and endangered species. Students taking the graduate version complete different assignments.
S. Solomon, J. Knox-Hayes
No required or recommended textbooks

11.376 Urban Sustainability in Action
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Considers the theory and practice of urban sustainability. Introduces concepts of environmental sustainability, systems dynamics, ecological footprints, and environmental indicators. Investigates cutting-edge practices of cities in the US and around the world. Drawing on those examples, students work in and around the City of Boston on local sustainability initiatives.
Staff

11.377 Food Systems and the Environment
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
______
Explores the evolution of food production in the US and globally. Considers the science, economics, and politics behind the transition from pre-industrial to an industrial food system. Debates the costs and benefits of genetically modified food, organic agriculture, and local/regional food production. Focuses on the environmental sustainability and human-health consequences of different approaches, for both the developed and developing world.
Staff

11.378[J] Water Planning, Policy, and Design
______

Graduate (Fall) Can be repeated for credit
(Same subject as4.625[J])
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4625
Lecture: T9-12 (1-375) +final
______
Focuses on water in environmental planning, policy, and design. Draws together faculty and students who are working on water-related research projects to develop and maintain a current perspective on the field from the site to metropolitan and international scales. Limited to 15.
J. Wescoat
No textbook information available

11.380 Urban Climate Adaptation
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Examines the challenges cities face and strategies to prepare for the impacts of climate change. Particular attention to the needs of vulnerable populations and resource-constrained cities, global and national adaptation policies and funding mechanisms, and ways in which local government and community-based activities can promote climate-readiness.
Staff

11.381 Infrastructure Systems in Theory and Practice
______

Graduate (Fall)
Prereq: 14.01; 11.202 or 11.203; or by permission of instructor
Units: 3-0-9
TBA.
______
Examines theories of infrastructure from science and technology studies, history, economics, and anthropology in order to understand the prospects for change for many new and existing infrastructure systems. Examines how these theories are then implemented within systems in the modern city, including but not limited to, energy, water, transportation, and telecommunications infrastructure. Seminar is conducted with intensive group research projects, in-class discussions and debates.
D. Hsu
No textbook information available

11.382 Water Diplomacy: The Science, Policy, & Politics of Managing Shared Resources
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Examines the history and dynamics of international environmental treaty-making, or what is called environmental diplomacy. Emphasizes climate change and other atmospheric, marine resource, global waste management and sustainability-related treaties and the problems of implementing them. Reviews the legal, economic, and political dynamics of managing shared resources, involving civil society on a global basis, and enforcing transboundary agreements. Focuses especially on principles from international relations, international law, environmental management, and negotiation theory as they relate to common-pool resource management.
L. Susskind

11.383[J] Managing Sustainable Businesses for People and Profits
______

Graduate (Spring)
(Same subject as15.662[J])
Prereq: None
Units: 3-6-3
______
Examines opportunities and challenges involved in building and growing businesses that achieve high financial performance and provide good jobs and careers to employees. Students engage participants in the MITx online course title Shaping the Future of Work to learn about the expectations and employment experiences of workers across the world. Through readings, cases, simulations and class visits from industry leaders, explores the underlying principles and business practices that help to secure that alignment between business health and societal well-being.
T. Kochan

11.384 Preparation for Malaysia Sustainable Cities Fieldwork
______

Graduate (Fall); partial term
Prereq: Permission of instructor
Units: 0-0-3 [P/D/F]
TBA.
______
Under faculty supervision, students conduct independent research to familiarize themselves with the culture, economy, politics, geography, ecology, and history of Malaysia. Selection by application.
L. Susskind
No textbook information available

11.385 Malaysia Sustainable Cities Fieldwork
______

Graduate (IAP)
Prereq: 11.384
Units: 3-0-3 [P/D/F]
______
Investigates sustainable development efforts of regional development agencies in Penang, Kuala Lumpur, or Johor Bahru. In addition to these sites, students visit the government city of Putrajaya, the World Heritage cities of George Town in Penang and Malacca, and Kuching in East Malaysia. Selection by application.
L. Susskind

11.386 Malaysia Sustainable Cities Practicum
______

Graduate (Spring); partial term
Prereq: 11.385
Units: 2-0-1
______
Examines examples of city development that reflect a commitment to the principles of sustainability, including economic development that ensures ecological sustainability, strategies for addressing intercultural tensions, and environmental quality improvements catalyzed by city development.
L. Susskind

11.401 Introduction to Housing, Community and Economic Development
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Lecture: TR9.30-11 (9-451)
______
Provides a critical introduction to the shape and determinants of political, social and economic inequality in America. Explores equitable development as a response framework for planners; social capital and community building as planning concepts; and the history, development, and current prospects of the fields of housing (with an emphasis on affordability and inclusion) and local economic development. Considers multiple scales but primarily the neighborhood, city/town, and metro region, centered on the interplay of policies, institutions and markets.
J. Steil
Textbooks (Fall 2016)

11.402 Urban Politics: Race and Political Change
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: None
Units: 3-0-9
______
Examines the place of US cities in political theory and practice. Particular attention given to contemporary issues of racial polarization, demographic change, poverty, sprawl, and globalization. Specific cities are a focus for discussion.
J. P. Thompson

11.404 Housing Policy and Planning in the US and Abroad
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Explores the policy tools and planning techniques used to formulate and implement housing strategies at local, state and federal levels. Topics include America's housing finance system and the causes of instability in mortgage markets; economic and social inequity in access to affordable housing; approaches to meeting community housing needs through local and state planning programs; programs for addressing homelessness; and emerging ideas about sustainable development and green building related to housing development and renovation. Introduces comparative policy approaches from other countries.
J. Buckley

11.405 Political Economy & Society
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of Instructor
Units: 3-0-6
______
Focuses on the connection (or not) between mind (theory) and matter (lived experience). Examines basic tenets of classical and recent political economic theories and their explication in ideas of market economies, centrally planned economies, social market economies, and co-creative economies. Assesses theories according to their relation to the lived experiences of people in communities and workplaces.
J. P. Thompson

11.406 Key Ideas in City Planning History and Theory
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
TBA.
______
Investigates the evolution of the ideals, the profession, and the practice of city planning throughout history by looking at key ideas that have driven theorists and practitioners. Explores city and regional planning in the light of broader historical trends, such as changing ideas about who cities are for; different approaches to urban problem-solving; variable factors affecting how urban settlements should be organized and re-organized; the development of human understanding about relationships between the built and natural environments; and about the effects of urban form and organization on society. Focuses substantially but not entirely upon the American experience.
Staff
No textbook information available

11.407 Economic Development Tools and Techniques
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR11-12.30 (9-451)
______
Introduces a suite of tools representing the basic set of practices used in the development field. Presents a wealth creation framework that focuses on place, improving livelihoods, incentivizing collaboration, creating multiple forms of wealth, and promoting local ownership. Students work with web-based tools designed for use in a professional setting. Discussions are based on results from tools, their interpretation, and their meaning. Relevant to all students interested in the structure and function of local, state, national and international economic contexts. Students develop a series of memos as students they complete assignments.
A. Glasmeier
No textbook information available

11.427[J] Urban Labor Markets and Employment Policy
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as15.677[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Discusses the broader trends in the labor market, how urban labor markets function, public and private training policy, other labor market programs, the link between labor market policy and economic development, and the organization of work within firms.
P. Osterman

11.430[J] Leadership in Real Estate
______

Graduate (Fall); first half of term
(Same subject as15.941[J])
Prereq: None
Units: 3-0-3
Ends Oct 21. Lecture: MW10.30-12 (9-357)
______
Designed to help students deepen their understanding of leadership and increase self-awareness. They examine authentic leadership styles and create goals and a learning plan to develop their capabilities. They also participate in activities to strengthen their "leadership presence" - the ability to authentically connect with people's hearts and minds. Students converse with leaders to learn from their insights, experiences, and advice. Limited to 15.
G. Schuck
Textbooks (Fall 2016)

11.431[J] Real Estate Finance and Investment
______

Graduate (Fall)
(Same subject as15.426[J])
Prereq: Permission of instructor
Units: 4-0-8
Lecture: MW4-5.30 (9-354) Recitation: M EVE (5.30-7 PM) (9-354)
______
Concepts and techniques for analyzing financial decisions in commercial property development and investment. Topics include property income streams, urban economics, discounted cash flow, equity valuation, leverage and income tax considerations, development projects, and joint ventures.
D. Geltner
Textbooks (Fall 2016)

11.432[J] Real Estate Capital Markets
______

Graduate (Spring); first half of term
(Same subject as15.427[J])
Prereq: 11.431; 15.402 or 15.414
Units: 2-0-4
______
Introduces real estate capital markets for institutional investors. Topics include real estate investment trusts (REIT), commercial mortgage-backed securities (CMBS), and private equity. Concepts and techniques for investment analysis include portfolio theory and equilibrium asset pricing. Additional topics may include price indexing and derivatives.
D. Geltner

11.433[J] Real Estate Economics
______

Graduate (Fall)
(Same subject as15.021[J])
Prereq: 14.01, 15.010, or 15.011
Units: 4-0-8
Lecture: TR11-12.30 (4-270) Recitation: M9-10.30 (9-354) +final
______
Develops understanding of the fundamental economic factors that shape the market for real property, as well as the influence of capital markets in asset pricing. Analyzes of housing as well as commercial real estate. Covers demographic analysis, regional growth, construction cycles, urban land markets, and location theory. Exercises and modeling techniques for measuring and predicting property demand, supply, vacancy, and prices.
W. C. Wheaton
Textbooks (Fall 2016)

11.434[J] Tools for Analysis: Design for Real Estate and Infrastructure Development
______

Graduate (Spring); second half of term
(Same subject as15.428[J],IDS.671[J])
Prereq: None
Units: 2-0-4
______
Introduction to analytical tools to support design and decision-making in real estate, infrastructure development, and investment. Particular focus on identifying and valuing sources of flexibility using "real options," Monte-Carlo simulation, and other techniques from the field of engineering systems. Integrates economic and engineering perspectives, and is suitable for students with various backgrounds. Provides useful preparation for thesis work in the area.
D. Geltner, R. de Neufville

11.435 Mixed-Income Housing Development
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Lecture: MW2.30-4 (9-357)
______
Provides an overview of affordable and mixed-income housing development for students who wish to understand the fundamental issues and requirements of urban scale housing development, and the process of planning, financing and developing such housing. Students gain practical experience assembling a mixed-income housing development proposal.
P. Roth
No textbook information available

11.436 Housing Studio: Neighborhood Sustainability Plan
______

Graduate (Spring)
Prereq: 11.401, 11.301, or 11.601
Units: 6-0-9
______
Explores ways to improve housing quality and affordability, increase energy savings, and promote transportation access as part of a neighborhood sustainability plan. Students work with a local client to define the terms of local sustainability for a specific Boston neighborhood, then design an appropriate framework for action for the target site focusing on existing and future housing needs, community services, transit connections, and energy policy.
Staff

11.437 Financing Economic Development
______

Graduate (Fall)
(Subject meets with11.137)
Prereq: None
Units: 4-0-8
Lecture: MW11-12.30 (8-205) Recitation: F1.30 (10-401)
______
Focuses on financing tools and program models to support local economic development. Provides an overview of private capital markets and financing sources to understand capital market imperfections that constrain economic development, business accounting, financial statement analysis, federal economic development programs, and public finance tools. Covers policies and program models, including revolving loan funds, guarantee programs, venture capital funds, bank holding companies, community development loan funds and credit unions, micro enterprise funds, and the Community Reinvestment Act. Students taking graduate version complete additional assignments. Limited to 25.
K. Seidman
Textbooks (Fall 2016)

11.438 Economic Development Planning
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 11.203, 11.220
Units: 3-0-9
______
Focuses on the policy tools and planning techniques used to formulate and implement local economic development strategies. Includes an overview of economic development theory, discussion of major policy areas and practices employed to influence local economic development, a review of analytic tools to assess local economies and how to formulate strategy. Coursework includes formulation of a local economic development strategy for a client.
K. Seidman

11.439 Revitalizing Urban Main Streets
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 11.401 or 11.301J or 11.328J
Units: 4-0-11
______
Workshop explores the integration of economic development and physical planning interventions to revitalize urban commercial districts. Covers: an overview of the causes of urban business district decline, revitalization challenges, and the strategies to address them; the planning tools used to understand and assess urban Main Streets from both physical design and economic development perspectives; and the policies, interventions, and investments used to foster urban commercial revitalization. Students apply the theories, tools and interventions discussed in class to preparing a formal neighborhood commercial revitalization plan for a client business district.
K. Seidman, S. Silberberg

11.444[J] The New Global Planning Practitioner
______

Graduate (Spring)
(Same subject as4.232[J])
(Subject meets with4.233)
Prereq: Permission of instructor
Units: 3-0-6
______
Considers a new interdisciplinary paradigm of practice that regards dialogue among practitioners and users essential for efficacious and creative design and planning process. Focuses on non-traditional client groups: communities, the poor, and the generally excluded middle-income. Explores key issues confronting development practitioners, with stress on practical exercises drawn from current national and international case studies; e.g., an investigative comparison of cities or tools in coping with impending rapid and massive growth and expansion. Engages those with a design and community service orientation. Additional work required of students taking the graduate version.
R. Goethert

11.450 Real Estate Development Building Systems
(New)
______

Graduate (Fall); first half of term
Prereq: None
Units: 2-0-1
Ends Oct 21. Lecture: R3-5 (9-354)
______
Provides students with a concise overview of the range of building systems that are encountered in professional commercial real estate development practice in the USA. Focuses on the relationship between real estate product types, building systems, and the factors that real estate development professionals must consider when evaluating these products and systems for a specific development project. Surveys commercial building technology including Foundation, Structural, MEP/FP, Envelope, and Interiors systems and analyzes the factors that lead development professionals to select specific systems for specific product types. One or more field trips to active construction sites may be scheduled during non-class hours based on student availability.
Y. Tsipis
No required or recommended textbooks

11.457 More than Data: Smart Cities, Big Data, Civic Technology and Policy
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: None
Units: 3-0-6
______
Discussions of future directions in the 'smart cities' debate. Begins by framing the current smart city with past trends such as the efficient city movement of the 1930s and the Modernist city of the 1950s and 60s. Examines current trends in big data, civic apps, Code for America, the open data movement, DIY data collections devices, and their policy impacts.
S. Williams

11.458 Crowd Sourced City: Civic Tech Prototyping Class
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Investigates the use of social medial and digital technologies for planning and advocacy by working with actual planning and advocacy organizations to develop, implement, and evaluate prototype digital tools. Students use the development of their digital tools as a way to investigate new media technologies that can be used for planning.
S. Williams

11.461[J] Technocracy
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject asSTS.463[J])
Prereq: None
Units: 3-0-9
______
Survey of the history of efforts to apply scientific methods and technological tools to solve social and political problems, with a focus on the United States since 1850. Topics include: city planning, natural resource management, public education, economic development, quantification and modeling in the social and policy sciences, technology transfer, and political economies of expertise.
J. S. Light

11.463[J] Structuring Low-Income Housing Projects in Developing Countries
______

Graduate (Fall)
(Same subject as4.236[J])
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4236
Lecture: R9-12 (1-375) +final
______
Examines dynamic relationship among key actors: beneficiaries, government, and funder. Emphasis on cost recovery, affordability, replicability, user selection, and project administration. Extensive case examples provide basis for comparisons.
R. Goethert
No required or recommended textbooks

11.466[J] Technology, Globalization, and Sustainable Development
______

Graduate (Fall)
(Same subject as1.813[J],15.657[J],IDS.437[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: W EVE (4-6.30 PM) (E51-376)
______
Investigates sustainable development, taking a broad view to include not only a healthy economic base, but also a sound environment, stable employment, adequate purchasing power, distributional equity, national self-reliance, and maintenance of cultural integrity. Explores national, multinational, and international political and legal mechanisms to further sustainable development through transformation of the industrial state. Addresses the importance of technological innovation and the financial crisis of 2008.
N. Ashford
Textbooks (Fall 2016)

11.468[J] SIGUS Workshop
______

Graduate (Fall, IAP) Can be repeated for credit
(Same subject as4.230[J])
(Subject meets with4.231)
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4230
Lecture: W EVE (5-6.30 PM) (2-103)
______
Interdisciplinary projects and interactive practices in urban settlement issues as investigated by MIT's SIGUS (Special Interest Group in Urban Settlements), with a focus on developing countries throughout the world. Participation by guest practitioners. Additional work required of students taking the graduate version.
R. Goethert
No required or recommended textbooks

11.469 Urban Sociology in Theory and Practice
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Introduction to core writings in urban sociology. Examines key theoretical paradigms that have comprised the field since its founding. Explores the nature and changing character of the city and the urban experience in the US and abroad, providing context for development and application of planning skills and sensibilities as well as urban research. Topics include the changing nature of community, social inequality, culture, political power, socio-spatial change, technological change, and the relationship between the built environment and human behavior.
J. Steil

11.470 The Politics of Development Policy
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Examines the political forces and conditions that affect urban, regional, and national development policymaking. Key protagonists include political parties, state actors, social movements, NGOs (domestic and global), business groups, and labor organizations, both formal and informal. Primary emphasis is the developing world, but seeks parallels across a variety of comparative and historical contexts.
Staff

11.472[J] D-Lab: Development
______

Graduate (Fall)
(Same subject asEC.781[J])
(Subject meets with11.025[J],EC.701[J])
Prereq: None
Units: 3-2-7
Lecture: MWF3.30-5 (N51-310)
______
Issues in international development, appropriate technology and project implementation addressed through lectures, case studies, guest speakers and laboratory exercises. Students form project teams to partner with community organizations in developing countries, and formulate plans for an optional IAP site visit. (Previous field sites include Ghana, Brazil, Honduras and India.) Recitation sections focus on specific project implementation, and include cultural, social, political, environmental and economic overviews of the target countries as well as an introduction to the local languages. Enrollment limited by lottery; must attend first class session.
S. L. Hsu, A. B. Smith, B. Sanyal
No textbook information available

11.474 D-Lab: Disseminating Water, Sanitation and Hygiene Innovations for the Common Good
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets withEC.715)
Prereq: None
Units: 3-0-6
______
Focuses on disseminating water, sanitation and hygiene (WASH) innovations in developing countries, especially among underserved communities. Structured around field-based learning, case studies, lectures and videos. Emphasis on core WASH principles, culture-specific solutions, appropriate and sustainable technologies, behavior change, social marketing and building partnerships. Term project entails implementing the "next steps" in a WASH innovation in a specific locale and/or a new proposal/plan/project. Long-term commitment to specific real-world WASH projects which have been disseminated by MIT faculty, students and alumni. Students taking graduate version complete additional assignments. Limited to 30.
S. E. Murcott

11.475 Navigating Power in Water and Sanitation Planning
______

Graduate (Spring)
Prereq: Open to undergraduates with permission of instructor
Units: 3-0-9
______
Informs and prepares students to navigate the explicit and implicit power dynamics among stakeholders in decision-making processes that govern the planning and delivery of water and sanitation systems. Through investigations of organization, regulation, financing, physical delivery, and research designs, students examine the trajectory of decisions that shape and influence the accessibility, affordability, and adequacy of water and sanitation services, particularly in vulnerable neighborhoods in mostly urban and peri-urban areas. Emphasis is placed on the importance of moving beyond the limited dimensions of supply and demand studies and gaining fluency in the multiplicative political-economic and social factors driving choices in water and sanitation systems planning. In-depth, globally comparative readings inform the course, and expose basic services in water and sanitation as a misnomer.
G. Carolini

11.476 Urbanizing China
______

Graduate (Fall)
Not offered regularly; consult department
(Subject meets with11.146)
Prereq: Permission of instructor
Units: 2-0-7
URL: http://dusp.mit.edu/subject/fall-2014-11s945
______
Discusses China's daunting urban challenges: congestion and smog, housing affordability, land reform and urban financing, migrants and locals, and social and spatial inequality. Provides examples of laudable achievements and diverse and innovative responses across more than six hundred cities. Presents China's urbanization as the joint result of natural socioeconomic processes and conscious actions by governments, markets, and the public. Presents multidisciplinary approaches and alternative narratives. Examines the intricate interaction between state and market in China's context, yielding a variety of state-market 'cocktails' devised and experimented in different cities in response to local problems, each involving a multilayered projection onto urban space. Students taking graduate version complete additional assignments.
J. Zhao

11.477[J] Urban Energy Systems and Policy
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as1.286[J])
(Subject meets with11.165)
Prereq: 11.203, 14.01, or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Examines efforts in developing and advanced nations and regions. Examines key issues in the current and future development of urban energy systems, such as technology, use, behavior, regulation, climate change, and lack of access or energy poverty. Case studies on a diverse sampling of cities explore how prospective technologies and policies can be implemented. Includes intensive group research projects, discussion, and debate.
D. Hsu

11.478 Behavior and Policy: Connections in Transportation
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Examines the behavioral foundation for policy design, using urban transportation examples. Introduces multiple frameworks of understanding behavior, contrasting perspectives of classic economic theory with behavioral economics and social psychology, suggests corresponding policy interventions and establishes a mapping between behavior, theory, and policy. Presents a spectrum of instruments for positively influencing behavior and improving welfare. Challenges students to critique, design, implement and interpret experiments that nudge travel behavior. Brings behavioral insights to creative design of transport policies that are efficient and equitable as well as simple, consistent, transparent, acceptable, and adaptive to behavioral changes.
J. Zhao

11.479[J] Water, Sanitation, Hygiene and Environmental Sanitation (WASH-ENV) in Low- and Middle-income Countries
______

Graduate (Spring)
(Same subject as1.851[J])
Prereq: None
Units arranged
______
Addresses principles and practice of water, sanitation, hygiene and environmental sanitation (WASH-ENV) systems, infrastructure, engineering, and planning in low- and middle-income countries. Incorporates interdisciplinary technical, socio-cultural, public health, human rights, behavioral, and economic aspects into the design and implementation of interventions. Students develop skills to plan simple, yet reliable, WASH-ENV systems together with urban or rural communities that are compatible with local customs and available human and material resources.
Staff

11.480 Urbanization and Development
______

Graduate (Spring)
(Subject meets with11.140)
Prereq: None
Units: 3-0-9
______
Examines developmental dynamics of rapidly urbanizing locales, with a special focus on the developing world. Case studies from India, China, Mexico, Brazil, and South Africa form the basis for discussion of social, spatial, political and economic changes in cities spurred by the decline of industry, the rise of services, and the proliferation of urban mega projects. Emphasizes the challenges of growing urban inequality, environmental risk, citizen displacement, insufficient housing, and the lack of effective institutions for metropolitan governance. Students taking graduate version complete additional assignments.
Staff

11.481[J] Analyzing and Accounting for Regional Economic Change
______

Graduate (Spring)
(Same subject as1.284[J])
Prereq: 14.03, 14.04
Units: 3-0-9
______
Surveys theories of regional growth, factor mobility, clustering, industrial restructuring, learning regions, and global supply chains from a political-economy perspective. Examines/critiques multipliers, linkages, and supply chains used to assess employment and environmental impacts, energy and infrastructure investments, and accounting issues related to the underground economy, work in the home, and environmental degradation. Assesses price indices, industrial location and employment measures, and shift-share analyses. Discussions of US and foreign applications.
Staff

11.482[J] Regional Socioeconomic Impact Analyses and Modeling
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as1.285[J])
Prereq: 11.481J or permission of instructor
Units: 2-1-9
URL: http://web.mit.edu/11.482/www/Syllabus482-2001.html
______
Reviews regional economic theories and models and provides students with experience in using alternative economic impact assessment models on microcomputers. Problem sets are oriented around infrastructure, housing, energy, and environmental issues. Students work with a client generally in Boston and make a presentation to the client. Emphasis on written and oral presentation skills.
K. R. Polenske

11.483 Housing and Land Use in Rapidly Urbanizing Regions
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Studies current urban controversies over affordable housing, land redevelopment, and public space, with special attention to property rights. Reviews how law, economics, sociology and planning theories frame these issues and interplays them with spatial approaches of urban design and geography. Explores cases that use property rights strategies to increase economic growth and social justice, providing insight for future design and policymaking. Topics include land trusts for affordable housing, mixed-use public space, and critical cartography.
Y. Hong

11.484 Project Appraisal in Developing Countries
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with11.144)
Prereq: Permission of instructor
Units: 3-0-9
______
Covers techniques of financial analysis of investment expenditures, as well as the economic and distributive appraisal of development projects. Critical analysis of these tools in the political economy of international development is discussed. Topics include appraisal's role in the project cycle, planning under conditions of uncertainty, constraints in data quality and the limits of rational analysis, and the coordination of an interdisciplinary appraisal team. Students taking graduate version complete additional assignments. Enrollment limited; preference to majors.
Y. Hong

11.487 Budgeting and Finance for the Public Sector
______

Graduate (Spring)
(Subject meets with11.147)
Prereq: None
Units: 3-0-9
______
Examines globally relevant challenges of adequately and effectively attending to public sector responsibilities for basic services with limited resources. Particular attention to the contexts of fiscal crises and rapid population growth, as well as shrinkage, through an introduction to methods and processes of budgeting, accounting, and financial mobilization. Case studies and practice exercises explore revenue strategies, demonstrate fiscal analytical competencies, and familiarize students with pioneering examples of promising budget and accounting processes and innovative funding mobilization via taxation, capital markets, and other mechanisms (e.g., land-value capture). Students taking graduate version explore the subject in greater depth.
G. Carolini

11.488 Urban Development in Conflict Cities: Planning Challenges and Policy Innovations
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of Instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Economic, religious, gender and ethnic differences must be negotiated every day in the urban arena. When tensions and conflict escalates into violence, the urban space becomes the battlespace in which these tensions are negotiated. Examines urban development challenges in conflict cities through multiple disciplinary perspectives on urban conflict. Review of the literature about when violence and cities intersect. Focuses on policy innovations, and an examination of potential planning, design, and policy solutions.
Staff

11.490 Law and Development
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 2-0-10
______
Examines the role of law in development and introduces economic and legal theories. Topics include formality/informality of property, contracts and bargaining in the shadow of the law, institutions for transparency and accountability, legitimation of law, sequencing of legal reform, and international economic law aspects. Studies the roles of property rights in economic development, the judiciary and the bureaucracy in development, and law in aid policy. Includes selected country case studies. Limited to 15.
B. Rajagopal

11.491[J] Economic Development and Policy Analysis
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as17.176[J])
Prereq: 11.701
Units: 3-0-9
______
Examines the process of economic development to understand why some countries or regions within countries have increased their incomes and reduced their poverty faster than others. Economic development is treated as a process of learning, as countries weigh theories and role models as guides for policy formulation and institution building. Historical and empirical examination of three role models for development/underdevelopment, as formulated by the Third World's new intelligentsia that emerged after de-colonization: the OPEC development role model, the East Asian role model, and the Brazilian role model.
Staff

11.493 Property and Land Use Law for Planners
______

Not offered academic year 2017-2018Graduate (Fall)
(Subject meets with11.183)
Prereq: None
Units: 3-0-9
Lecture: W2-5 (9-450B)
______
Examines legal and institutional arrangements for the establishment, transfer, and control over property under American and selected comparative systems including India and South Africa. Focuses on key issues of property and land use law regarding planning and economic development. Emphasizes just and efficient resource use; institutional, entitlement and social relational approaches to property; distributional and other social aspects; and the relationship between property, culture, and democracy. Students taking graduate version complete additional assignments.
B. Rajagopal
No textbook information available

11.495 Governance and Law in Developing Countries
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 2-0-10
______
Examines the multiple dimensions of governance in international development with a focus on the role of legal norms and institutions in the balance between state and the market. Analyzes changes in the distribution of political and legal authority as a result of economic globalization. Topics include the regulation of firms; forms of state and non-state monitoring; varieties of capitalism, global governance and development; and good governance, including transparency and accountability mechanisms, the role of the judiciary and legal culture, and tools for measuring governance performance.
B. Rajagopal

11.496 Law, Social Movements, and Public Policy: Comparative and International Experience
______

Graduate (Spring)
(Subject meets with11.166)
Prereq: Permission of instructor
Units: 3-0-9
______
Studies the interaction between law, courts, and social movements in shaping domestic and global public policy. Examines how groups mobilize to use law to affect change and why they succeed and fail. Case studies explore the interplay between law, social movements, and public policy in current issues, such as gender, race, labor, trade, climate change/environment, and LGBTQ rights. Introduces theories of public policy, social movements, law and society, and transnational studies. Students taking graduate version complete additional assignments. Limited to 15.
B. Rajagopal

11.497 Human Rights at Home and Abroad
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with11.164[J],17.391[J])
Prereq: None
Units: 3-0-9
______
Provides a rigorous and critical introduction to the history, foundation, structure, and operation of the human rights movement. Focuses on key ideas, actors, methods and sources, and critically evaluates the field. Addresses current debates in human rights, including the relationship with security, democracy, development and globalization, urbanization, equality (in housing and other economic and social rights; women's rights; ethnic, religious and racial discrimination; and policing/conflict), post-conflict rebuilding and transitional justice, and technology-related issues. Students taking graduate version expected to write a research paper.
B. Rajagopal

11.520 Workshop on Geographic Information Systems
______

Graduate (Fall, Spring); partial term
Prereq: 11.205 or permission of instructor
Units: 2-2-2
Begins Oct 31. Lecture: MW2.30-4 (9-354) Lab: M EVE (5-7 PM) (W31-301) or T EVE (5-7 PM) (W31-301) or W EVE (5-7 PM) (W31-301) or R EVE (5-7 PM) (W31-301)
______
An introduction to geographic information systems (GIS) as applied to urban and regional planning, community development, and local government. Emphasis on learning GIS technology and spatial analysis techniques through extensive hands-on exercises using real-world data sets such as the US census of population and housing. Includes a small project on an urban planning problem involving the selection of appropriate methods, the use of primary and secondary data, computer-based modeling, and spatial analysis. Enrollment limited; preference to MCP students.
Fall:S. Williams
Spring:J. Ferreira
No textbook information available

11.521 Spatial Database Management and Advanced Geographic Information Systems
______

Graduate (Spring)
Prereq: Permission of instructor; or 11.520 andCoreq: 11.220
Units: 3-3-6
Credit cannot also be received for11.523,11.524
______
Extends the computing and geographic information systems (GIS) skills developed in 11.520 to include spatial data management in client/server environments and advanced GIS techniques. First half covers the content of 11.523, introducing database management concepts, SQL (Structured Query Language), and enterprise-class database management software. Second half explores advanced features and the customization features of GIS software that perform analyses for decision support that go beyond basic thematic mapping. Includes the half-term GIS project of 11.524 that studies a real-world planning issue.
J. Ferreira

11.522 Research Seminar on Urban Information Systems
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: 11.521 or permission of instructor
Units: 2-4-6
______
Advanced research seminar enhances computer and analytic skills developed in other subjects in this sequence. Students present a structured discussion of journal articles representative of their current research interests involving urban information systems and complete a short research project. Suggested research projects include topics related to ongoing UIS Group research.
J. Ferreira

11.523 Fundamentals of Spatial Database Management
______

Graduate (Spring); first half of term
Prereq: Permission of instructor
Units: 2-2-2
Credit cannot also be received for11.521,11.524
______
The fundamentals of database management systems as applied to spatial analysis. Includes extensive hands-on exercises using real-world planning data. Introduces database management concepts, SQL (Structured Query Language), and enterprise-class database software. Same content as first half of 11.521.
J. Ferreira

11.524 Advanced Geographic Information System Project
______

Graduate (Spring) Can be repeated for credit; second half of term
Prereq: 11.523 or permission of instructor
Units arranged
Credit cannot also be received for11.521,11.523
______
Learning and utilizing advanced geographic information system techniques in studio/lab setting with real-world client problem and complex digital spatial data infrastructure. Projects typically use the client and infrastructure setting for 11.521. Credit cannot also be received for 11.521 in the same term.
J. Ferreira

11.526[J] Comparative Land Use and Transportation Planning
______

Graduate (Spring)
(Same subject as1.251[J])
Prereq: Permission of Instructor
Units: 3-0-9
______
Focuses on the integration of land use and transportation planning, drawing from cases in both industrialized and developing countries. Reviews underlying theories, analytical techniques, and the empirical evidence of the land use-transportation relationship at the metropolitan, intra-metropolitan, and micro-scales. Also covers the various ways of measuring urban structure, form, and the "built environment." Develops students' skills to assess relevant policies, interventions and impacts.
C. Zegras

11.527 Advanced Seminar in Transportation Finance
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 2-1-9
______
Focuses on the theory and practice of transportation system finance, examining the range of relevant topics including basic public finance, politics, institutional structures, externalities, pricing, and the role of advanced technologies. Primarily oriented around land-based, surface transportation, although in their research students are welcome to examine air and maritime modes according to their interests. Explores issues across a range of contexts, including North America, Europe, Latin America, and Asia.
C. Zegras

11.533 Ecological Planning with GIS
______

Graduate (Spring)
Prereq: 11.205
Units: 3-3-6
______
Provides a practical introduction to spatial environmental assessment and planning methods, from landscape to regional scales. Lectures and discussions focus on key concepts in landscape ecology as well as the data and methods needed to incorporate these concepts in environmental planning. Weekly lab exercises demonstrate how natural systems are represented in modern geographic information systems, how to synthesize information using overlay analysis and suitability modeling, and design methods that build on the resulting syntheses. Features raster GIS analysis methods.
Staff

11.540[J] Urban Transportation Planning
______

Graduate (Fall)
(Same subject as1.252[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: F2-5 (5-217)
______
Studies the history, policy, practice and politics of urban transportation. Covers the role of the federal, state, and local government and the MPO, public transit in the auto era, analysis of current trends and pattern breaks; analytical tools for transportation planning, traffic engineering and policy analysis; the contribution of transportation to air pollution, social costs and climate change; land use and transportation interactions; traffic and place making; bicycles, pedestrians, and traffic calming. Examples from the Boston area and from Bilbao.
F. Salvucci, M. Murga
No textbook information available

11.541[J] Public Transportation Systems
______

Graduate (Spring)
(Same subject as1.258[J])
Prereq: 1.201 or permission of instructor
Units: 3-0-9
______
Discusses evolution and role of urban public transportation modes, systems and services, focusing on bus and rail. Describes technological characteristics and their impacts on capacity, service quality, and cost. Current practice and new methods for data collection and analysis, performance monitoring, route and network design, frequency determination, and vehicle and crew scheduling. Effect of pricing policy and service quality on ridership. Methods for estimating costs associated with proposed service changes. Organizational models for delivering public transportation service including finance and operations.
Staff

11.543[J] Transportation Policy, the Environment, and Livable Communities
______

Graduate (Spring)
(Same subject as1.253[J])
(Subject meets with1.153)
Prereq: Permission of instructor
Units: 3-0-9
______
Examines the economic and political conflict between transportation and the environment. Investigates the role of government regulation, green business and transportation policy as a facilitator of economic development and environmental sustainability. Analyzes a variety of international policy problems, including government-business relations, the role of interest groups, non-governmental organizations, and the public and media in the regulation of the automobile; sustainable development; global warming; politics of risk and siting of transport facilities; environmental justice; equity; as well as transportation and public health in the urban metropolis. Provides students with an opportunity to apply transportation and planning methods to develop policy alternatives in the context of environmental politics. Students taking graduate version complete additional assignments.
J. Coughlin

11.544[J] Transportation Systems Analysis: Performance and Optimization
______

Graduate (Fall)
(Same subject as1.200[J])
Prereq: 1.010, permission of instructor
Units: 3-1-8
Lecture: TR10.30-12 (3-370) Recitation: R4 (3-370)
______
Problem-motivated introduction to methods, models and tools for the analysis and design of transportation networks including their planning, operations and control. Capacity of critical elements of transportation networks. Traffic flows and deterministic and probabilistic delay models. Formulation of optimization models for planning and scheduling of freight, transit and airline systems, and their solution using software packages. User- and system-optimal traffic assignment. Control of traffic flows on highways, urban grids, and airspace.
C. Osorio
No required or recommended textbooks

11.545[J] Transportation Systems Analysis: Demand and Economics
______

Graduate (Fall)
(Same subject as1.201[J])
Prereq: Permission of instructor
Units: 3-1-8
Lecture: TR2.30-4 (2-105) Recitation: F11 (2-105) +final
______
Covers the key principles governing transportation systems planning and management. Introduces the microeconomic concepts central to transportation systems. Topics include economic theories of the firm, consumer, and market, demand models, discrete choice analysis, cost models and production functions, and pricing theory. Applications to transportation systems - including congestion pricing, technological change, resource allocation, market structure and regulation, revenue forecasting, public and private transportation finance, and project evaluation - cover urban passenger transportation, freight, maritime, aviation, and intelligent transportation systems.
Staff
Textbooks (Fall 2016)

11.601 Introduction to Environmental Policy and Planning
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Lecture: TR9.30-11 (56-167)
______
Required introductory subject for graduate students pursuing environmental policy and planning as their specialization in the MCP Program. Also open to other graduate students interested in environmental policymaking and the practice of environmental planning. Taught comparatively, with numerous references to examples from around the world. Four major areas of focus: National Environmental Policymaking, Environmental Ethics, Environmental Forecasting and Analysis Techniques, and Strategies for Collaborative Decision-making.
L. Susskind
Textbooks (Fall 2016)

11.630[J] Environmental Law, Policy, and Economics: Pollution Prevention and Control
______

Graduate (Fall)
(Same subject as1.811[J],IDS.430[J])
(Subject meets with1.801[J],11.021[J],17.393[J])
Prereq: Permission of instructor for undergraduates
Units: 3-0-9
Credit cannot also be received for15.663
Lecture: TR3.30-5 (E51-057) +final
______
Reviews and analyzes federal and state regulation of air and water pollution, hazardous wastes, and the production and use of toxic chemicals. Analyzes pollution as an economic problem and the failure of markets. Emphasizes use of legal mechanisms and alternative approaches (such as economic incentives and voluntary approaches) to control pollution and to encourage chemical accident and pollution prevention. Focuses on the major federal legislation, the underlying administrative system, and the common law in analyzing environmental policy, economic consequences, and the role of the courts. Discusses classical pollutants and toxic industrial chemicals, community right-to-know, and environmental justice. Also provides an introduction to basic legal skills. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C. Caldart
Textbooks (Fall 2016)

11.631[J] Regulation of Chemicals, Radiation, and Biotechnology
______

Graduate (Spring)
Not offered regularly; consult department
(Same subject as1.812[J],IDS.431[J])
(Subject meets with1.802[J],10.805[J],11.022[J],IDS.436[J])
Prereq: 1.811 or permission of instructor
Units: 3-0-9
______
Focuses on policy design and evaluation in the regulation of hazardous substances and processes. Includes risk assessment, industrial chemicals, pesticides, food contaminants, pharmaceuticals, radiation and radioactive wastes, product safety, workplace hazards, indoor air pollution, biotechnology, victims' compensation, and administrative law. Health and economic consequences of regulation, as well as its potential to spur technological change, are discussed for each regulator regime. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C.Caldart

11.701 Introduction to International Development Planning
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Lecture: TR9.30-11 (9-450B)
______
Studies interaction between planners and institutions at different scales, from local to global/transnational. Emphasizes a historical and institutional approaches to development planning. Includes an overview of theories of development, state, organizational arrangements, and implementation mechanisms. Covers current topics in development planning, such as decentralization, participatory planning, urban-rural linkages, corruption, legal institutions and post-conflict development. Analyzes various roles planners play in different institutional contexts. Restricted to first-year MCP and SPURS students.
B. Rajagopal
No textbook information available

Tutorials, Research, and Fieldwork Subjects

11.800 Reading, Writing and Research
______

Graduate (Spring)
Prereq: Permission of instructor,Coreq: 11.801
Units: 3-0-6 [P/D/F]
______
Required subject intended solely for 1st-year DUSP PhD students. Helps students prepare their first-year papers and plan for a dissertation. Focuses on how scholars get original ideas and write about them clearly and engagingly. Assignments ask students to apply generic readings and methods to individual first-year paper topics. Students work simultaneously with advisor on first-year paper, and present papers in the final weeks of the semester.
Staff

11.801 Doctoral Research Paper
______

Graduate (Spring)
Prereq: Permission of instructor,Coreq: 11.800
Units: 3-0-6
______
Students develop a first-year research paper in consultation with their advisor.
Staff

11.901 Independent Study: Urban Studies and Planning
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

11.902 Independent Study: Urban Studies and Planning
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Opportunity for independent study under regular supervision by a faculty member.
Staff
No required or recommended textbooks

11.903 Supervised Readings in Urban Studies
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

11.904 Supervised Readings in Urban Studies
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Reading and discussion of topics in urban studies and planning.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

11.905 Research Seminar in Urban Studies and Planning
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

11.906 Research Seminar in Urban Studies and Planning
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Special research issues in urban planning.
Staff
No required or recommended textbooks

11.907 Urban Fieldwork
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

11.908 Urban Fieldwork
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Practical application of planning techniques to towns, cities, and regions, including problems of replanning, redevelopment, and renewal of existing communities. Includes internships, under staff supervision, in municipal and state agencies and departments.
Staff
No required or recommended textbooks

11.909 Graduate Tutorial
______

Graduate (Fall) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Planned programs of instruction for a minimum of three students on a planning topic not covered in regular subjects of instruction. Registration subject to prior arrangement with appropriate faculty member.
Staff
No textbook information available

11.910 Doctoral Tutorial
______

Graduate (Fall)
Prereq: None
Units: 3-0-3 [P/D/F]
Selected dates. Lecture: R11-12.30 (9-450B)
______
Required subject exclusively for first-year DUSP PhD candidates, but with multiple colloquium sessions open to the full department community. Introduces students to a range of department faculty (and others) by offering opportunities to discuss applications of planning theory and planning history. Assists in clarifying the departments intellectual diversity. Encourages development of a personal intellectual voice and capacity to synthesize and respond to the arguments made by others.
L. Vale, J. Zhao
No required or recommended textbooks

11.920 Planning in Practice
(New)
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of Instructor
Units: 0-0-3 [P/D/F]
TBA.
______
Provides practical experience through internships secured by the student in the field of urban planning.
M. Daly
No textbook information available

11.960 Independent Study: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
No textbook information available

11.961 Independent Study: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Opportunity for independent study under regular supervision by a faculty member.
Staff
No textbook information available

11.962 Fieldwork: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Practical application of real estate techniques in the field.
Staff
No textbook information available

11.963 Independent Study: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No textbook information available

11.964 Independent Study: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Opportunity for independent study under regular supervision by a faculty member.
Staff
No textbook information available

11.985 Summer Field Work
______

Graduate (Summer)
Prereq: None
Units arranged [P/D/F]
______
Practical application of planning techniques over the summer with prior arrangement.
S. Wellford
No textbook information available

11.S938 Special Subject: Urban Studies and Planning
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
URL: http://dusp.mit.edu/subject/fall-2016-11s938
Lecture: TR2-3.30 (9-450B)
______
No textbook information available

11.S939 Special Subject: Urban Studies and Planning
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No textbook information available

11.S940-11.S944 Special Subject: Urban Studies and Planning
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
11.S940: URL: http://dusp.mit.edu/subject/fall-2016-11s940
11.S941: URL: http://dusp.mit.edu/subject/fall-2016-11s941
11.S942: URL: http://dusp.mit.edu/subject/fall-2016-11s942
11.S943: URL: http://dusp.mit.edu/subject/fall-2014-11s943
11.S944: URL: http://dusp.mit.edu/subject/fall-2014-11s944
11.S940: Lecture: W EVE (4-6 PM) (10-401)
11.S941: Lecture: T EVE (4-6 PM) (9-450A)
11.S942: Lecture: W2-4 (9-217)
11.S943: TBA.
11.S944: TBA.
______
For graduate students wishing to pursue further study in advanced areas of urban studies and city and regional planning not covered in regular subjects of instruction.
M. Kothari
11.S940: No textbook information available
11.S941: No textbook information available
11.S942: No required or recommended textbooks
11.S943: No textbook information available
11.S944: No textbook information available

11.S945-11.S949 Special Subject: Urban Studies and Planning
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
11.S945: URL: http://dusp.mit.edu/subject/fall-2016-11s945
11.S946: URL: http://dusp.mit.edu/subject/spring-2016-11s946
11.S947: URL: http://dusp.mit.edu/subject/spring-2016-11s947
11.S948: URL: http://dusp.mit.edu/subject/spring-2016-11s948
11.S949: URL: http://dusp.mit.edu/subject/spring-2016-11s949
11.S945: Lecture: W EVE (2-6 PM) (9-255A)
______
For graduate students wishing to pursue further study in advanced areas of urban studies and city and regional planning not covered in regular subjects of instruction.
Staff
11.S945: No required or recommended textbooks

11.S950-11.S957 Special Seminar: Urban Studies and Planning
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
11.S950: URL: https://dusp.mit.edu/subject/fall-2016-11s950-0
11.S951: URL: http://dusp.mit.edu/subject/spring-2016-11s951
11.S952: URL: http://dusp.mit.edu/subject/spring-2016-11s952
11.S953: URL: http://dusp.mit.edu/subject/spring-2016-11s953
11.S955: URL: http://dusp.mit.edu/subject/fall-2014-11s955
11.S950: TBA.
11.S951: TBA.
11.S952: TBA.
11.S953: TBA.
11.S955: TBA.
11.S956: TBA.
11.S957: TBA.
______
For graduate students wishing to pursue further study in advanced areas of urban studies and city and regional planning not covered in regular subjects of instruction
Staff
11.S950: No textbook information available
11.S951: No textbook information available
11.S952: No textbook information available
11.S953: No textbook information available
11.S955: No textbook information available
11.S956: No textbook information available
11.S957: No textbook information available

11.S958 Special Seminar: Urban Studies and Planning
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______

11.S959 Special Seminar: Urban Studies and Planning
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
For graduate students wishing to pursue further study in advanced areas of urban studies and city and regional planning not covered in regular subjects of instruction.
Staff

11.S965 Special Subject: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No textbook information available

11.S966, 11.S967 Special Subject: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
11.S967: Begins Oct 17. Lecture: W10.30-12 (4-159)
______
11.S967: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

11.S968 Special Seminar: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
11.S968: TBA.
11.S969: TBA.
______
11.S968: No textbook information available
11.S969: No textbook information available

11.S969 Special Seminar: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit; first half of term
Prereq: Permission of instructor
Units arranged [P/D/F]
11.S968: TBA.
11.S969: TBA.
______
11.S968: No textbook information available
11.S969: No textbook information available

11.S970 Special Seminar: Real Estate
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
11.S968: TBA.
11.S969: TBA.
______
Small group study of advanced subjects under staff supervision. For graduate students wishing to pursue further study in advanced areas of real estate not covered in regular subjects of instruction.
Staff
11.S968: No textbook information available
11.S969: No textbook information available

11.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: M9.30-11 (9-255) Recitation: W9.30-11 (10-485, 9-451, 9-217)
______
Program of research and writing of thesis; to be arranged by the student with supervising committee.
Staff
Textbooks arranged individually


left arrow|Undergraduate: 11.00-11.199
plus UROP, ThU, ThT
|Graduate: 11.20-11.299|Graduate: 11.30-11.999 plus ThG|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 12: Earth, Atmospheric, and Planetary Sciences
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Course 12: Earth, Atmospheric, and Planetary Sciences
Fall 2016


Undergraduate Subjects

Core and General Science Subjects

12.000 Solving Complex Problems
______

Undergrad (Fall)
Prereq: None
Units: 1-2-6
Lecture: MWF3 (16-160)
______
Provides an opportunity for entering freshmen to gain firsthand experience in integrating the work of small teams to develop effective solutions to complex problems in Earth system science and engineering. Each year's class explores a different problem in detail through the study of complementary case histories and the development of creative solution strategies. Includes exercises in website development, written and oral communication, and team building. Subject required for students in the Terrascope freshman program, but participation in Terrascope is not required of all 12.000 students. Students who pass 12.000 are eligible to participate in the Terrascope field trip the following spring. Limited to freshmen.
D. McGee
No textbook information available

12.001 Introduction to Geology
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: None
Units: 3-4-5
Lecture: MWF1 (54-819) Lab: MWF2 (54-819)
______
Major minerals and rock types, rock-forming processes, and time scales. Temperatures, pressures, compositions, structure of the Earth, and measurement techniques. Geologic structures and relationships observable in the field. Sediment movement and landform development by moving water, wind, and ice. Crustal processes and planetary evolution in terms of global plate tectonics with an emphasis on ductile and brittle processes. Includes laboratory exercises on minerals, rocks, mapping, plate tectonics, rheology, glaciers. Two one-day field trips (optional).
EAPS Staff
Textbooks (Fall 2016)

12.002 Introduction to Geophysics and Planetary Science
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: Physics II (GIR), Calculus II (GIR)
Units: 3-1-8
______
Study of the structure, composition, and physical processes governing the terrestrial planets, including their formation and basic orbital properties. Topics include plate tectonics, earthquakes, seismic waves, rheology, impact cratering, gravity and magnetic fields, heat flux, thermal structure, mantle convection, deep interiors, planetary magnetism, and core dynamics. Suitable for majors and non-majors seeking general background in geophysics and planetary structure.
L. H. Royden, B. Weiss

12.003 Introduction to Atmosphere, Ocean, and Climate Dynamics
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR), Physics I (GIR)
Units: 3-1-8
URL: http://www.mit.edu/~pog/12.003/Home.html
Lecture: MWF11 (54-1623) Recitation: TBA +final
______
Introduces the dynamical processes that govern the atmosphere, oceans, and climate. Topics include Earth's radiation budget, convection and clouds, the circulation of the atmosphere and ocean, and climate change. Illustrates underlying mechanisms through laboratory demonstrations with a rotating table, and through analysis of atmospheric and oceanic data.
P. O'Gorman
Textbooks (Fall 2016)

12.006[J] Nonlinear Dynamics: Chaos
______

Undergrad (Fall)
(Same subject as 2.050[J],18.353[J])
Prereq: 18.03 or 18.034; Physics II (GIR)
Units: 3-0-9
Lecture: TR1-2.30 (2-105)
______
Introduction to nonlinear dynamics and chaos in dissipative systems. Forced and parametric oscillators. Phase space. Periodic, quasiperiodic, and aperiodic flows. Sensitivity to initial conditions and strange attractors. Lorenz attractor. Period doubling, intermittency, and quasiperiodicity. Scaling and universality. Analysis of experimental data: Fourier transforms, Poincare sections, fractal dimension, and Lyapunov exponents. Applications to mechanical systems, fluid dynamics, physics, geophysics, and chemistry. See 12.207J/18.354J for Nonlinear Dynamics: Continuum Systems.
P-T. Brun
Textbooks (Fall 2016)

12.007 Geobiology: History of Life on Earth
______

Undergrad (Spring)
Prereq: None
Units: 3-0-9
______
Surveys the interactive Earth system: biology in geologic, environmental and climate change throughout Earth's history. Introduces the concept of "life as a geological agent" and examines the interaction between biology and the Earth system during the roughly 4 billion years since life first appeared. Topics include the origin of the solar system and the early Earth atmosphere; the origin and evolution of life and its influence on climate up through and including the modern age and the problem of global warming; the global carbon cycle; and astrobiology.
T. Bosak, G. Fournier

12.009[J] Nonlinear Dynamics: The Natural Environment
______

Undergrad (Spring)
(Same subject as18.352[J])
Prereq: Physics I (GIR), Calculus II (GIR);Coreq: 18.03
Units: 3-0-9
______
Analyzes cooperative processes that shape the natural environment, now and in the geologic past. Emphasizes the development of theoretical models that relate the physical and biological worlds, the comparison of theory to observational data, and associated mathematical methods. Topics include carbon cycle dynamics; ecosystem structure, stability and complexity; mass extinctions; biosphere-geosphere coevolution; and climate change. Employs techniques such as stability analysis; scaling; null model construction; time series and network analysis.
D. H. Rothman

12.010 Computational Methods of Scientific Programming
______

Undergrad (Fall)
Prereq: Calculus II (GIR), Physics I (GIR)
Units: 4-0-8
Lecture: TR2-4 (54-517)
______
Introduces programming languages and techniques used by physical scientists: FORTRAN, C, C++, MatLab, and Mathematica. Emphasis on program design, algorithm development and verification, and comparative advantages and disadvantages of different languages. Students first learn the basic usage of each language, common types of problems encountered, and techniques for solving a variety of problems encountered in contemporary research: examination of data with visualization techniques, numerical analysis, and methods of dissemination and verification. No prior programming experience is required.
T. Herring, C. Hill
No textbook information available

12.011[J] Archaeological Science
______

Undergrad (Spring) HASS Social Sciences
(Same subject as3.985[J],5.24[J])
Prereq: Chemistry (GIR) or Physics I (GIR)
Units: 3-1-5
______
Pressing issues in archaeology as an anthropological science. Stresses the natural science and engineering methods archaeologists use to address these issues. Reconstructing time, space, and human ecologies provides one focus; materials technologies that transform natural materials to material culture provide another. Topics include 14C dating, ice core and palynological analysis, GIS and other remote sensing techniques for site location, soil micromorphology and site formation, sourcing of metal artifacts, and microstructural and mechanical analyses of cementitious materials used in ancient monumental buildings.
H. N. Lechtman

12.012 MatLab, Statistics, Regression, Signal Processing
______

Undergrad (Fall)
(Subject meets with12.444)
Prereq: None.Coreq: 18.06
Units: 3-0-9
Lecture: TR11-12.30 (54-824)
______
Introduces the basic tools needed for data analysis and interpretation in the Geosciences, as well as other sciences. Composed of four modules, targeted at introducing students to the basic concepts and applications in each module. MatLab: Principles and practice in its uses, script and function modules, basic approaches to solving problems. Statistics: Correlation, means, dispersion, precision, accuracy, distributions, central limit theorem, skewness, probability, Chi-Square, Gaussian and other common distributions used in hypothesis testing. Regression: Random and grid search methods, basic least squares and algorithms applicable to regression, inversion and parameter estimation. Signal Processing: Analog and digital signals, Z-transform, Fourier series, fast Fourier transforms, spectral analysis leakage and bias, digital filtering. Students taking the graduate version complete different assignments.
F. D. Morgan, T. A. Herring, S. Ravela
No textbook information available

12.021 Earth Science, Energy, and the Environment
______

Undergrad (Fall)
Prereq: Physics I (GIR), Calculus I (GIR), Chemistry (GIR)
Units: 3-1-8
Lecture: MWF1 (8-119) +final
______
Provides understanding of the Earth System most relevant to production of our planet's natural energy resources, including the physics, chemistry, and biology of conventional and alternative energy sources. Includes a broad overview of traditional and alternative energy sources: hydrocarbons (conventional and unconventional), nuclear, geothermal, hydroelectric, and wind and tides, along with their potentials and limitations. Develops detailed knowledge of the formation, concentration, and production of fossil and nuclear fuels, as well as the waste products associated with their consumption. An examination of conventional and alternative energy sources includes the environmental issues associated with the exploitation of these resources, both regional and global.
B. H. Hager
No textbook information available

12.031A[J] Fundamentals of Ecology I
______

Undergrad (Fall); first half of term
(Same subject as1.018A[J],7.30A[J])
Prereq: None
Units: 2-0-4
Ends Oct 21. Lecture: TR11-12.30 (48-316) Recitation: M4 (48-316) or R4 (48-308)
______
Fundamentals of ecology, considering Earth as an integrated dynamic living system. Coevolution of the biosphere and geosphere, biogeochemical cycles, metabolic diversity, primary productivity, competition and the niche, trophic dynamics and food webs, population growth and limiting factors. Combination of 1.018A and 1.018B counts as REST subject.
O. Cordero, M. Follows
No required or recommended textbooks

12.031B[J] Fundamentals of Ecology II
______

Undergrad (Fall); second half of term
(Same subject as1.018B[J],7.30B[J])
Prereq: 1.018A
Units: 2-0-4
Begins Oct 24. Lecture: TR11-12.30 (48-316) Recitation: M4 (48-316) or R4 (48-308) +final
______
Advanced topics in Ecology. Population modeling, global carbon cycle, climate change, geoengineering, theories of resource competition and mutualism, allometric scaling, ecological genomics, niche theory, human population growth. Applied ecology. Combination of 1.018A and 1.018B counts as REST subject.
O. Cordero, M. Follows
No required or recommended textbooks

12.086 Modeling Environmental Complexity
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with12.586)
Prereq: 18.03
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduction to mathematical and physical models of environmental processes. Emphasis on the development of macroscopic continuum or statistical descriptions of complex microscopic dynamics. Problems of interest include: random walks and statistical geometry of landscapes; percolation theory and transport in disordered media; fractals, scaling, and universality; ecological dynamics and the structure of ecosystems, food webs, and other natural networks; kinetics of biogeochemical cycles. Appropriate for advanced undergraduates. Beginning graduate students are encouraged to register for 12.586. Students taking the graduate version complete different assignments.
D. H. Rothman

12.090 Current Topics in Earth, Atmospheric, and Planetary Sciences
______

Undergrad (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No textbook information available

12.091 Current Topics in Earth, Atmospheric, and Planetary Sciences
______

Undergrad (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Laboratory or field work in earth, atmospheric, and planetary sciences. Consult with department Education Office.
EAPS Faculty

12.092 Current Topics in Geology and Geochemistry
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

12.093 Current Topics in Geology and Geochemistry
______

Undergrad (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Laboratory or field work in geology and geochemistry. To be arranged with department faculty. Consult with department Education Office.
EAPS Faculty

12.094 Current Topics in Geophysics
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

12.095 Current Topics in Geophysics
______

Not offered academic year 2016-2017Undergrad (IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Laboratory or field work in geophysics. To be arranged with department faculty. Consult with department Education Office.
EAPS Faculty

12.096 Current Topics in Atmospheric Science and Oceanography
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

12.097 Current Topics in Atmospheric Science and Oceanography
______

Undergrad (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Laboratory or field work in atmospheric science and oceanography. To be arranged with department faculty. Consult with department Education Office.
EAPS Faculty

12.098 Current Topics in Planetary Science
______

Undergrad (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Laboratory or field work in planetary science. To be arranged with department faculty. Consult with department Education Office.
EAPS Staff

12.099 Current Topics in Planetary Science
______

Undergrad (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Laboratory or field work in planetary science. To be arranged with department faculty. Consult with department Education Office.
EAPS Faculty

Geology and Geochemistry

12.102 Environmental Earth Science
______

Undergrad (Fall) Rest Elec in Sci & Tech
Not offered regularly; consult department
Prereq: None
Units: 3-0-9
______
The geologic record demonstrates that our environment has changed over a variety of time scales from seconds to billions of years. Explores the many ways in which geologic processes control and modify the Earth's environment. Topics include chemical and physical interactions between the solid Earth, its oceans and atmosphere; the effect of catastrophic events such as volcanic eruptions and earthquakes on the environment; geologic hazards; and our role in modifying the environment through Earth resource development. Serves as an introduction to 12.120, which addresses field applications of these principles in the American Southwest.
S. A. Bowring

12.104 Geochemistry of the Earth and Planets
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: Calculus II (GIR)
Units: 3-2-7
Subject Cancelled Subject Cancelled
______
Focuses on low-temperature geochemistry and the Earth's biogeochemical cycles, including the biologic and inorganic chemical processes that create chemical variability and element partitioning among lithosphere, hydrosphere and atmosphere. Covers basic thermodynamics, aqueous chemistry, major and trace element geochemistry, and stable isotopic geochemistry.
S. Ono, D. McGee

12.108 Structure of Earth Materials
______

Undergrad (Fall)
Prereq: Chemistry (GIR)
Units: 3-4-5
Lecture: WF3-4.30 (54-819) Lab: WF9-11 (54-819) +final
______
Provides a comprehensive introduction to crystalline structure, crystal chemistry, and bonding in rock-forming minerals. Introduces the theory relating crystal structure and crystal symmetry to physical properties such as refractive index, elastic modulus, and seismic velocity. Surveys the distribution of silicate, oxide, and metallic minerals in the interiors and on the surfaces of planets, and discusses the processes that led to their formation.
T. L. Grove
Textbooks (Fall 2016)

12.109 Petrology
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 12.108
Units: 3-6-6
______
Surveys the distribution, chemical composition, and mineral associations in rocks of the Earth's crust and upper mantle, and establishes its relation to tectonic environment. Emphasis is on the use of chemistry and physics to interpret rock forming processes. Topics include dynamics of crust and mantle melting as preserved in the chemical composition of igneous rocks and minerals, the long-term record of global climate change as preserved in the minerals of sedimentary rocks, and the time-temperature-depth record preserved in minerals of metamorphosed crustal rocks.
T. L. Grove

12.110 Sedimentology and Stratigraphy
______

Not offered academic year 2017-2018Undergrad (Spring)
(Subject meets with12.465)
Prereq: 12.001
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Studies sediments in the rock cycle; production of sediments at the Earth's surface; physics and chemistry of sedimentary materials; scale and geometry of near-surface sedimentary bodies, including aquifers; sediment transport and deposition in modern sedimentary environments; and burial and lithification. Surveys major sedimentary rock types. Also covers stratigraphic relationships of sedimentary basins, and evolution of sedimentary processes through geologic time. Includes two or three weekend days of field trips. Students taking graduate version complete additional assignments.
K. Bergmann

12.113 Structural Geology
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 12.001
Units: 3-3-6
URL: http://web.mit.edu/12.113/www/
Subject Cancelled Subject Cancelled
______
Introduces mechanics of rock deformation. Discusses recognition, interpretation, and mechanics of faults, folds, structural features of igneous and metamorphic rocks, and superposed deformations. Introduces regional structural geology and tectonics. Laboratory includes techniques of structural analysis, recognition and interpretation of structures on geologic maps, and construction of interpretive cross sections.
O. Jagoutz

12.114 Field Geology I
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 12.108 or permission of instructor; orCoreq: 12.113
Units: 2-2-2 [P/D/F]
______
Introduces techniques of geological field study. Weather permitting, several weekend field exercises provide practical experience in preparation for 12.115. Presents introductory material on the regional geology of the locale of 12.115.
B. C. Burchfiel, O. Jagoutz

12.115 Field Geology II
______

Not offered academic year 2016-2017Undergrad (IAP) Institute Lab
Prereq: 12.113, 12.114
Units: 0-12-0
______
During January, students practice methods of modern geological field study off-campus during an intensive four-week experience. Exercises include geological and geomorphological mapping on topographic and photographic base maps of a wide variety of bedrock and surficial rocks. Where feasible, geochemical and geophysical field measurements are corrrelated with geology.
O. Jagoutz

12.116 Analysis of Geologic Data
______

Undergrad (Spring)
Prereq: 12.115
Units: 0-2-4
______
Includes in-depth laboratory analysis of samples, interpretation of geological data, and where possible, geophysical and geochemical data. Includes the preparation of reports based on the field studies conducted in 12.115 during January; report generally exceeds 30 pages in length and includes one major revision and rewrite. Instruction in writing techniques provided.
B. C. Burchfiel, O. Jagoutz

12.119 Analytical Techniques for Studying Environmental and Geologic Samples
______

Undergrad (Spring) Institute Lab
Prereq: None
Units: 2-6-4
______
Focuses on analytical facilities that are used to determine elemental and isotopic abundances in soils, rocks, minerals, and fluids. Emphasis is on isotopic ratios Sr, Nd, and Pb, whose isotopic ratios can be used for geochronology, and abundances of trace elements such as Rb, Sr, Cu, Cd, Hg, rare-earths, Pb, Th, and U. Analytical techniques include mass spectrometry, emission spectrometry, atomic absorption, neutron activation, and electron microprobe. A major lab project utilizes these techniques to address specific environmental and geologic problems.
E. Boyle, T. Grove

12.120 Environmental Earth Science Field Course
______

Not offered academic year 2016-2017Undergrad (IAP)
Prereq: Permission of instructor
Units: 1-5-0
______
Field study to foster understanding of natural hazards and human influence on the environment. Class conducted in the western United States, at locations such as Death Valley and the White Mountain Research Station in Bishop California. Topics include water use and availability, climate change, earthquakes and faulting, and landslides. Also examines volcanic hazards and geothermal power, effects of river diversion, and the geology of the Yucca Mountain facility for the storage of radioactive waste. Students partially responsible for travel expenses. Designed to follow 12.001 or 12.102; other students will be accepted when space is available.
T. L. Grove

12.141 Electron Microprobe Analysis
______

Undergrad (IAP)
Prereq: None
Units: 1-1-4 [P/D/F]
______
Introduction to the theory of x-ray microanalysis through the electron microprobe including ZAF matrix corrections. Techniques to be discussed are wavelength and energy dispersive spectrometry, scanning backscattered electron, secondary electron, cathodoluminescence, and x-ray imaging. Lab sessions involve use of the electron microprobe.
T. Grove, N. Chatterjee

12.158 Molecular Biogeochemistry
______

Not offered academic year 2017-2018Undergrad (Fall)
(Subject meets with12.458)
Prereq: Permission of instructor
Units: 2-4-3 [P/D/F]
Lecture: T4-5.30 (E25-605)
______
Covers all aspects of molecular biosignatures, such as their pathways of lipid biosynthesis, the distribution patterns of lipid biosynthetic pathways with regard to phylogeny and physiology, isotopic contents, occurrence in modern organisms and environments, diagenetic pathways, analytical techniques and the occurrence of molecular fossils through the geological record. Students analyze in depth the recent literature on chemical fossils. Lectures provide background on the subject matter. Basic knowledge of organic chemistry required. Students taking graduate version complete additional assignments.
R. Summons
No required or recommended textbooks

12.163 Geomorphology
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with12.463)
Prereq: 12.001, Physics I (GIR), Calculus I (GIR); or permission of instructor
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Quantitative examination of processes that shape Earth's surface. Introduction to fluvial, hillslope, and glacial mechanics. Essentials of weathering, soil formation, runoff, erosion, slope stability, sediment transport, and river morphology. Landscape evolution in response to climatic and tectonic forcing. Application of terrestrial theory to planetary surfaces. Additional instruction in geographic information systems (GIS) and remote sensing analysis, field measurement techniques, and numerical modeling of surface processes. Students taking the graduate version complete different assignments.
T. Perron

12.170 Essentials of Geology
______

Undergrad (Fall)
Not offered regularly; consult department
(Subject meets with12.470)
Prereq: Physics II (GIR), Calculus II (GIR); or permission of instructor
Units: 4-0-8
______
Studies the geology of planetary interiors and surfaces, including plate tectonics, as a unifying theory of terrestrial geology, surface processes, and the Earth's interior. Covers igneous, metamorphic, and sedimentary processes associated with tectonic settings and the typical rock suites created; mineral and rock identification; and causes of compositional differences on many scales (mineral grains, rocks, regions of the Earth, different planets). Also addresses conditions required for melting and melting processes; rock structure and field techniques; and Earth history. Treatment of these topics includes discussions of the geochemical, petrologic, geochronological, experimental, or field techniques used to investigate them; the limitations of current geological techniques and geological controversies; and major geological expeditions, experiments, and studies from the past, along with their premises and results. Students taking graduate version complete additional assignments.
EAPS Staff

Geophysics

12.201 Essentials of Global Geophysics
______

Not offered academic year 2017-2018Undergrad (Fall)
(Subject meets with12.501)
Prereq: Physics II (GIR), 18.03
Units: 4-0-8
URL: http://quake.mit.edu/~fjsimons/12.201-12.501.html
Lecture: MWF9 (54-824) +final
______
Overview of basic topics in solid-earth geophysics, such as the Earth's rotation, gravity and magnetic field, seismology, and thermal structure. Formulation of physical principles presented in three one-hour lectures per week. Current applications discussed in an additional one-hour tutorial each week. Students taking graduate version complete different assignments.
R. van der Hilst
No textbook information available

12.207[J] Nonlinear Dynamics: Continuum Systems
______

Undergrad (Spring)
(Same subject as1.062[J],18.354[J])
(Subject meets with18.3541)
Prereq: 18.03 or 18.034; Physics II (GIR)
Units: 3-0-9
______
General mathematical principles of continuum systems. From microscopic to macroscopic descriptions in the form of linear or nonlinear (partial) differential equations. Exact solutions, dimensional analysis, calculus of variations and singular perturbation methods. Stability, waves and pattern formation in continuum systems. Subject matter illustrated using natural fluid and solid systems found, for example, in geophysics and biology.
P. Pearce

12.213 Alternate Energy Sources
______

Undergrad (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units: 1-4-1 [P/D/F]
______
Explores a number of alternative energy sources such as geothermal energy (heat from the Earth's interior), wind, natural gas, and solar energy. Includes a field trip to visit sites where alternative energy is being harvested or generated. Content and focus of subject varies from year to year.
F. D. Morgan

12.214 Essentials of Applied Geophysics
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with12.507)
Prereq: 18.03
Units: 3-3-6
______
Introduces the application of geophysical methods to all aspects of near-surface environmental and engineering geophysics, including the exploration for petroleum, water, and minerals. Topics include seismic, electrical, electromagnetic, ground penetrating radar, magnetics, gravity, rock physics and chemistry, borehole geophysics and the global positioning system (GPS). Uses a quantitative approach to emphasize basic principles and a physical /chemical understanding of each method. Discusses specific illustrative field examples. Lab work is mainly devoted to local field work and equipment preparation for the IAP Field Geophysics class. Students taking graduate version complete additional assignments.
F. D. Morgan, T. A. Herring, B. H. Hager

12.221 Field Geophysics
______

Not offered academic year 2016-2017Undergrad (IAP)
(Subject meets with12.511)
Prereq: 12.214
Units: 1-4-1 [P/D/F]
______
Covers practical methods of modern geophysics, including the global positioning system (GPS), gravity, and magnetics. Field work is conducted in western US and includes intensive 10-day field exercise. Focuses on measurement techniques and their interpretation. Introduces the science of gravity, magnetics, and the GPS. Measures crustal structure, fault motions, tectonic deformations, and the local gravity and magnetic fields. Students perform high-precision measurements and participate in data analysis. Emphasizes principles of geophysical data collection and the relevance of these data for tectonic faulting, crustal structure, and the dynamics of the earthquake cycle. Students taking graduate version complete additional assignments.
T. A. Herring, B. H. Hager, F. D. Morgan

12.222 Field Geophysics Analysis
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with12.512)
Prereq: 12.221
Units: 2-0-4
______
Focuses on in-depth data analysis and development of skills needed to report results both in writing and orally. Students use data collected in 12.221 to develop written and oral reports of the results, with each student focusing on a different area. For example, students can develop the geophysical modeling or synthesis of the results into other studies in the area. The final written and oral reports are combined into a comprehensive report and presentation of the field camp and its results. Students taking graduate version complete additional assignments.
T. A. Herring, B. H. Hager, F. D. Morgan

Atmospheres, Oceans, and Climate

12.300[J] Global Change Science
______

Not offered academic year 2016-2017Undergrad (Fall)
(Same subject as1.071[J])
Prereq: 18.03
Units: 3-0-9
______
Introduces the basic relevant principles and concepts in atmospheric physics, climate dynamics, biogeochemistry, and water and energy balance at the land-atmosphere boundary, through an examination of two current problems in the global environment: carbon dioxide and global warming; and tropical deforestation and regional climate. An introduction to global environmental problems for students in basic sciences and engineering.
E. A. B. Eltahir

12.301 Climate Science
______

Undergrad (Fall)
(Subject meets with12.842)
Prereq: Chemistry (GIR), 18.03, or permission of instructor
Units: 4-0-8
Lecture: MWF2 (54-824)
______
Introduction to climate studies, including beginnings of the solar system, time scales, and climate in human history; methods for detecting climate change, including proxies, ice cores, instrumental records, and time series analysis; physical and chemical processes in climate, including primordial atmosphere, ozone chemistry, carbon and oxygen cycles, and heat and water budgets; internal feedback mechanisms, including ice, aerosols, water vapor, clouds, and ocean circulation; climate forcing, including orbital variations, volcanism, plate tectonics, and solar variability; climate models and mechanisms of variability, including energy balance, coupled models, and global ocean and atmosphere models; and outstanding problems. Students taking the graduate version complete different assignments.
K. Emanuel, E. Boyle, D. McGee
Textbooks (Fall 2016)

12.306 Atmospheric Physics and Chemistry
______

Undergrad (Spring)
(Subject meets with10.571[J],12.806[J])
Prereq: 5.60 or 5.61; 18.075; or permission of instructor
Units: 3-0-9
______
Introduction to the physics and chemistry of the atmosphere including experience with computer codes. Aerosols and theories of their formation, evolution, and removal. Gas and aerosol transport from urban to continental scales. Coupled models of radiation, transport, and chemistry. Solution of inverse problems to deduce emissions and removal rates. Emissions control technology and costs. Applications to air pollution and climate. Students taking the graduate version complete different assignments.
R. G. Prinn

12.307 Weather and Climate Laboratory
______

Undergrad (Spring) Institute Lab
Prereq: Calculus II (GIR), Physics I (GIR)
Units: 1-4-10
URL: http://paoc.mit.edu/12307/
______
A laboratory subject intended to illustrate, by means of hands-on projects, the basic dynamical and physical principles which govern the general circulation of the atmosphere and the day-to-day sequence of weather events. Real-time meteorological observations are studied together with laboratory fluid experiments. Projects based on real-time observations stress the analysis and dynamical interpretation of the real phenomena, while complementary rotating tank experiments stress planning and testing of ideas in a more controlled laboratory environment. Written critical summaries of the results of each project and oral presentations are an integral part of the subject.
L. Illari, J. Marshall

12.310 An Introduction to Weather Forecasting
______

Undergrad (IAP)
Prereq: Physics I (GIR), Calculus I (GIR)
Units: 1-1-4 [P/D/F]
URL: http://paoc.mit.edu/synoptic/courses/12.310/12310.htm
______
Basic principles of synoptic meteorology and weather forecasting. Analysis of hourly weather data and numerical weather prediction models. Regular preparation of weather forecasts.
L. Illari

12.320A[J] Introduction to Hydrology and Water Resources
______

Undergrad (Fall); first half of term
(Same subject as1.070A[J])
Prereq: 1.060A;Coreq: 1.061A, 1.106
Units: 2-0-4
Ends Oct 21. Lecture: TR9.30-11 (48-316) Recitation: M1 (48-308)
______
Water in the environment; Water resource systems; The hydrologic cycle at its role in the climate system; Surface water and energy balance; evaporation and transpiration through vegetation; Precipitation formation, infiltration, storm runoff, and flood processes; Groundwater aquifers, subsurface flow and the hydraulics of wells.
D. Entekhabi
No textbook information available

12.320B[J] Introduction to Hydrology Modeling
______

Undergrad (Fall); second half of term
(Same subject as1.070B[J])
Prereq: 1.070A
Units: 2-0-4
Begins Oct 24. Lecture: TR9.30-11 (48-316) Recitation: M1 (48-308)
______
Develops understanding of numerical modeling of aquifers, groundwater flow and contaminant transport, as well as uncertainty and risk analysis for water resources.
D. Entekhabi
No textbook information available

12.330[J] Fluid Physics
______

Undergrad (Spring)
(Same subject as8.292[J])
Prereq: 8.044, 5.60, or permission of instructor
Units: 3-0-9
______
A physics-based introduction to the properties of fluids and fluid systems, with examples drawn from a broad range of sciences, including atmospheric physics and astrophysics. Definitions of fluids and the notion of continuum. Equations of state and continuity, hydrostatics and conservation of momentum; ideal fluids and Euler's equation; viscosity and the Navier-Stokes equation. Energy considerations, fluid thermodynamics, and isentropic flow. Compressible versus incompressible and rotational versus irrotational flow; Bernoulli's theorem; steady flow, streamlines and potential flow. Circulation and vorticity. Kelvin's theorem. Boundary layers. Fluid waves and instabilities. Quantum fluids.
D. Cziczo

12.333 Atmospheric Dynamics
______

Undergrad (Fall)
Not offered regularly; consult department
Prereq: 12.003, 8.03, 18.03; or permission of instructor
Units: 4-0-8
______
Discusses the dynamics of the atmosphere, with emphasis on the large scale. Topics include zonally symmetric circulations and the tropical Hadley circulation; internal gravity waves; balanced flows, potential vorticity conservation and Rossby waves; stability of zonal flows; baroclinic instability and extratropical storms; tropical waves, the Walker circulation, and El Niño and the Southern Oscillation; and the role of eddies in the general circulation. Students taking graduate version complete different assignments.
EAPS Staff

12.335 Experimental Atmospheric Chemistry
______

Undergrad (Fall) Institute Lab
(Subject meets with12.835)
Prereq: Chemistry (GIR)
Units: 2-4-6
Lecture: TR1.30-3 (54-1623)
______
Introduces the atmospheric chemistry involved in climate change, air pollution, and ozone depletion using a combination of interactive laboratory and field studies and simple computer models. Uses instruments for trace gas and aerosol measurements and methods for inferring fundamental information from these measurements. Provides instruction and practice in written and oral communication. Students taking the graduate version complete different assignments.
R. Prinn, S. Ono, K. Dryer
No required or recommended textbooks

12.336[J] Air Pollution
______

Undergrad (Fall)
(Same subject as1.085[J])
Prereq: 18.03
Units: 3-0-9
Lecture: MW10.30-12 (48-308)
______
Provides a working knowledge of basic air quality issues, with emphasis on a multidisciplinary approach to investigating the sources and effects of pollution. Topics include emission sources; atmospheric chemistry and removal processes; meteorological phenomena and their impact on pollution transport at local to global scales; air pollution control technologies; health effects; and regulatory standards. Discusses regional and global issues, such as acid rain, ozone depletion and air quality connections to climate change.
C. Heald
Textbooks (Fall 2016)

12.338 Aerosol and Cloud Microphysics and Chemistry
______

Undergrad (Spring)
(Subject meets with1.842[J],12.814[J])
Prereq: 12.335, 12.336 or permission of instructor
Units: 3-0-9
______
Focuses on understanding how aerosol particles form droplets or ice crystals during several atmospheric processes: determining Earth's radiative balance; heterogeneous chemistry and acid rain; understanding where, when and how much precipitation occurs. Provides tools for understanding the physics of aerosol and cloud element motion; the interaction of particles with water vapor, including phase changes and droplet and ice nucleation; the chemical composition of particles and the effect on cloud formation processes; and the effect of cloud processing on aerosol chemistry. Discusses relevant topics of contemporary interest, e.g., geoengineering and weather modification and volcanic effects. Students taking the graduate version complete different assignments.
D. Cziczo

12.340 Global Warming Science
______

Undergrad (Spring)
Prereq: Calculus I (GIR), Physics I (GIR), or permission of instructor;Coreq: 5.60
Units: 3-0-9
______
Provides students with a scientific foundation of anthropogenic climate change and an introduction to climate models. Focuses on fundamental physical processes that shape climate (e.g. solar variability, orbital mechanics, greenhouse gases, atmospheric and oceanic circulation, and volcanic and soil aerosols) and on evidence for past and present climate change. Discusses material consequences of climate change, including sea level change, variations in precipitation, vegetation, storminess, and the incidence of disease. Examines the science behind mitigation and adaptation proposals.
EAPS Staff

12.346[J] Global Environmental Negotiations
______

Undergrad (Fall)
(Same subject asIDS.062[J])
(Subject meets with12.846[J],IDS.525[J])
Prereq: Permission of instructor
Units: 2-0-4
Lecture: T2.30-4.30 (4-144)
______
Practical introduction to global environmental negotiations designed for science and engineering students. Covers basic issues in international negotiations, such as North-South conflict, implementation and compliance, trade, and historical perspective on global environmental treaties. Offers hands-on practice in developing and interpreting international agreements through role-play simulations and observation of ongoing climate change negotiating processes. Students taking graduate version complete additional assignments.
N. E. Selin
Textbooks (Fall 2016)

12.348[J] Global Climate Change: Economics, Science, and Policy
______

Undergrad (Spring)
(Same subject as15.026[J])
(Subject meets with12.848[J],15.023[J])
Prereq: Calculus II (GIR); 5.60; 14.01 or 15.010; or permission of instructor
Units: 3-0-6
______
Introduces scientific, economic, and ecological issues underlying the threat of global climate change, and the institutions engaged in negotiating an international response. Develops an integrated approach to analysis of climate change processes, and assessment of proposed policy measures, drawing on research and model development within the MIT Joint Program on the Science and Policy of Global Change. Graduate students are expected to explore the topic in greater depth through reading and individual research. 12.340 recommended.
R. G. Prinn

12.349 Mechanisms and Models of the Global Carbon Cycle
______

Undergrad (Spring)
(Subject meets with12.849)
Prereq: Calculus II (GIR), Physics I (GIR)
Units: 3-0-9
______
Addresses changes in the ocean, terrestrial biosphere and rocks modulation of atmospheric carbon dioxide on timescales from months to millions of years. Includes feedbacks between carbon cycle and climate. Combines hands-on data analysis with the formulation of simple models rooted in basic physical, chemical and biological principles. Students create individual "toy" global carbon cycle models. Students taking graduate version complete different assignments.
M. Follows

12.385 Science, Politics, and Environmental Policy
______

Undergrad (Fall)
(Subject meets with11.373[J],12.885[J])
Prereq: Permission of instructor
Units: 3-0-6
Lecture: M EVE (3-6 PM) (54-1623)
______
Examines the role of science in US and international environmental policymaking. Surveys the methods by which scientists learn about the natural world; the treatment of science by experts, advocates, the media, and the public and the way science is used in legislative, administrative and judicial decision making. Through lectures, group discussions, and written essays, students develop a critical understanding of the role of science in environmental policy. Potential case studies include fisheries management, ozone depletion, global warming, smog, and endangered species. Students taking the graduate version complete different assignments.
S. Solomon, J. Knox-Hayes
No required or recommended textbooks

Planetary Science and Astronomy

12.400 The Solar System
______

Undergrad (Spring) Rest Elec in Sci & Tech
Not offered regularly; consult department
Prereq: Physics I (GIR)
Units: 3-0-9
______
Introduction to the study of the solar system with emphasis on the latest spacecraft results. Subject covers basic principles rather than detailed mathematical and physical models. Topics include an overview of the solar system, planetary orbits, rings, planetary formation, meteorites, asteroids, comets, planetary surfaces and cratering, planetary interiors, planetary atmospheres, and life in the solar system.
R. P. Binzel

12.402[J] Introduction to Astronomy
______

Undergrad (Spring) Rest Elec in Sci & Tech
(Same subject as8.282[J])
Prereq: Physics I (GIR)
Units: 3-0-6
______
Quantitative introduction to physics of the solar system, stars, interstellar medium, the galaxy, and universe, as determined from a variety of astronomical observations and models. Topics: planets, planet formation; stars, the Sun, "normal" stars, star formation; stellar evolution, supernovae, compact objects (white dwarfs, neutron stars, and black holes), plusars, binary x-ray sources; star clusters, globular and open clusters; interstellar medium, gas, dust, magnetic fields, cosmic rays; distance ladder; galaxies, normal and active galaxies, jets; gravitational lensing; large scaling structure; Newtonian cosmology, dynamical expansion and thermal history of the universe; cosmic microwave background radiation; big bang nucleosynthesis. No prior knowledge of astronomy necessary. Not usable as a restricted elective by Physics majors.
Staff

12.409 Hands-On Astronomy: Observing Stars and Planets
______

Undergrad (Spring)
Prereq: None
Units: 0-4-2 [P/D/F]
______
Background for, and techniques of, visual observation and electronic imaging of the Moon, planets, satellites, stars, and brighter deep-space objects. Weekly outdoor observing sessions using 8-inch diameter telescopes when weather permits. Indoor sessions introduce skills necessary for observation. Introduction to contemporary observational astronomy including astronomical computing, image and data processing, and how astronomers work. Student must maintain a careful and complete written log which is graded. Consumes an entire evening each week; 100% attendance at observing sessions required to pass. Enrollment limited; priority to freshmen.
A. Bosh

12.410[J] Observational Techniques of Optical Astronomy
______

Undergrad (Fall) Institute Lab
(Same subject as8.287[J])
Prereq: 8.282J, 12.402J, 12.409, or other introductory astronomy course;Coreq: 8.03
Units: 3-4-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MWF1 (54-517) Lab: TBA
______
Fundamental physical and optical principles used for astronomical measurements at visible wavelengths and practical methods of astronomical observations. Topics: astronomical coordinates, time, optics, telescopes, photon counting, signal-to-noise ratios, data analysis (including least-squares model fitting), limitations imposed by the Earth's atmosphere on optical observations, CCD detectors, photometry, spectroscopy, astrometry, and time variability. Project at Wallace Astrophysical Observatory. Written and oral project reports. Limited to 18; preference to Course 8 and Course 12 majors and minors.
R. Binzel, A. Bosh
Textbooks (Fall 2016)

12.411 Astronomy Field Camp
______

Undergrad (IAP) Can be repeated for credit
Prereq: 12.410 or 8.287
Units: 0-6-3 [P/D/F]
______
Individual research projects in planetary science and astrophysics, involving supervised work at Lowell Observatory in Flagstaff, AZ. Projects may include observations made using Lowell's telescope facilities. Project topics and objectives vary from year to year. Written and oral reports required. Limited to 6.
A. Bosh

12.420 Physics and Chemistry of the Solar System
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with12.601)
Prereq: 12.002 or permission of instructor
Units: 3-0-9
______
Advanced applications of physical and chemical principles to the study of the solar system. Topics include terrestrial and giant planets, meteorites, asteroids, comets, Kuiper belt objects, rings, impact craters, interiors, surfaces, atmospheres, geomagnetism, cosmochemistry, remote sensing, formation and evolution of the solar system.
B. P. Weiss

12.425[J] Extrasolar Planets: Physics and Detection Techniques
______

Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject as8.290[J])
(Subject meets with12.625)
Prereq: 8.03, 18.03
Units: 2-1-9
Lecture: TR1.30-3 (54-824)
______
Presents basic principles of planet atmospheres and interiors applied to the study of extrasolar planets. Focuses on fundamental physical processes related to observable extrasolar planet properties. Provides a quantitative overview of detection techniques. Introduction to the feasibility of the search for Earth-like planets, biosignatures and habitable conditions on extrasolar planets. Students taking graduate version complete additional assignments.
S. Seager
No textbook information available

12.43[J] Space Systems Engineering
______

Undergrad (Spring)
(Same subject as16.83[J])
Prereq: Permission of instructor
Units: 3-3-6
______
Design of a complete space system, including systems analysis, trajectory analysis, entry dynamics, propulsion and power systems, structural design, avionics, thermal and environmental control, human factors, support systems, and weight and cost estimates. Students participate in teams, each responsible for an integrated vehicle design, providing experience in project organization and interaction between disciplines. Includes several aspects of team communication including three formal presentations, informal progress reports, colleague assessments, and written reports. Offered alternate Fall and Spring terms.
J. A. Hoffman, A. Saenz-Otero

12.431[J] Space Systems Development
______

Not offered academic year 2016-2017Undergrad (Spring) Institute Lab
(Same subject as16.831[J])
Prereq: Permission of instructor
Units: 2-10-6
______
Students build a space system, focusing on refinement of sub-system designs and fabrication of full-scale prototypes. Sub-systems are integrated into a vehicle and tested. Sub-system performance is verified using methods of experimental inquiry, and is compared with physical models of performance and design goals. Communication skills are honed through written and oral reports. Formal reviews include the Implementation Plan Review and the Acceptance Review. Knowledge of the engineering design process is helpful.
J. A. Hoffman, A. Saenz-Otero

Independent Research Subjects

12.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

12.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Undergraduate research opportunities in Earth, Atmospheric, and Planetary Sciences.
Consult Department UROP Coordinator
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

12.IND Independent Study
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: 12.TIP
Units arranged
______
Independent reading, laboratory, or fieldwork in Earth, Atmospheric, and Planetary Sciences. To be arranged by student and an appropriate EAPS faculty member. A written report may be required at the discretion of the advisor. Units arranged should reflect the project requirements.
Consult EAPS Education Office

12.TIP Thesis Preparation
______

Undergrad (Fall, Spring)
Prereq: None
Units: 2-0-4
TBA.
______
Definition of and early-stage work on the thesis project. Students develop a written research proposal and begin writing the supporting text of the thesis concurrent with conducting research for the thesis project. Supervision of the writing continues into the spring term which concludes with an oral presentation of the research results.
J. Connor
No required or recommended textbooks

12.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 12.TIP
Units arranged
TBA.
______
Program of research leading to the writing of a thesis; to be arranged by the student and an appropriate MIT faculty member.
EAPS Faculty
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|12.00-12.439 plus UROP, IND, TIP, ThU|12.440-12.599 plus ThG|12.600-12.999|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 12: Earth, Atmospheric, and Planetary Sciences
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Course 12: Earth, Atmospheric, and Planetary Sciences
Fall 2016


Graduate Subjects

12.440, 12.441 Collaborative Seminar in Geology and Geophysics
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Focuses on problems of current interest in geology and geophysics; subject matter varies from term to term. Includes guest speakers from outside of EAPS. 12.441 is graded P/D/F.
Geology and Geophysics Staff

12.442, 12.443 Collaborative Seminar in Planetary Science
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Focuses on problems of current interest in planetary science; subject matter varies from term to term. Includes guest speakers from outside of EAPS. 12.443 is graded P/D/F.
Planetary Science Staff

12.444 MatLab, Statistics, Regression, Signal Processing
______

Graduate (Fall)
(Subject meets with12.012)
Prereq: 18.06
Units: 3-0-9
Lecture: TR11-12.30 (54-824)
______
Introduces the basic tools needed for data analysis and interpretation in the Geosciences, as well as other sciences. Composed of four modules, targeted at introducing students to the basic concepts and applications in each module. MatLab: Principles and practice in its uses, script and function modules, basic approaches to solving problems. Statistics: Correlation, means, dispersion, precision, accuracy, distributions, central limit theorem, skewness, probability, Chi-Square, Gaussian and other common distributions used in hypothesis testing. Regression: Random and grid search methods, basic least squares and algorithms applicable to regression, inversion and parameter estimation. Signal Processing: Analog and digital signals, Z-transform, Fourier series, fast Fourier transforms, spectral analysis leakage and bias, digital filtering. Students taking the graduate version complete different assignments.
F. D. Morgan, T. A. Herring, S. Ravela
No textbook information available

12.445 Communication in the Earth, Atmospheric, and Planetary Sciences
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-3 [P/D/F]
Subject Cancelled Subject Cancelled
______
Concentrated instruction and practice in professional writing and presentation. Topics include review of various communication styles prevalent in the field; strategies for tailoring reports, technical papers, and presentations for specific audiences; and mechanics of organization and style. Weekly assignments in writing or speaking, with peer and instructor feedback. Limited to 6.
F. D. Morgan

12.446 Teaching Experience in EAPS
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Recognizes the educational value derived from satisfactory performance of assigned duties as a Teaching Assistant. Laboratory, field, recitation, or classroom teaching under supervision of a faculty member. Credit for this subject may not be used for any degree granted by Course 12. Total enrollment limited by availability of suitable teaching assignments.
EAPS Staff
No required or recommended textbooks

12.447 Strategies for Writing Successful Fellowship Proposals
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-0 [P/D/F]
______
Focuses on developing writing skills appropriate for preparing successful fellowship proposals. Includes writing practice, self-evaluation, and faculty feedback.
Staff

12.448, 12.449 Collaborative Seminar in Atmospheres, Oceans and Climate
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Focuses on problems of current interest in atmospheres, oceans, and climate; subject matter varies from term to term. Includes guest speakers from outside of EAPS. 12.449 is graded P/D/F.
PAOC Staff

12.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of an SM, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member.
Consult Department Headquarters
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

Geology and Geochemistry

12.450 Seminar in Geology and Geochemistry
______

Graduate (Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
______
Seminar on topics of current interest in geology and geochemistry. Required background preparation for students taking pre-doctoral general examinations in these subjects.
Geology and Geochemistry Staff

12.451 Seminar in Regional Tectonics
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-6 [P/D/F]
______
Applies techniques of tectonic synthesis to study the roles of particular orogenic belts in global plate tectonics. Treats different applications in different terms, so that the subject may be taken repeatedly to learn the range of orogenic responses to temporal and spatial variations of activity at plate boundaries.
B. C. Burchfiel, L. H. Royden

12.453-12.454 Crosby Lectures in Geology
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-6 [P/D/F]
______
A series of presentations on an advanced topic in the field of geology by the visiting William Otis Crosby lecturer. The Crosby lectureship is awarded to a distinguished international scientist each year to introduce new scientific perspectives to the MIT community. Subject content and structure vary from year to year.
Consult Department Education Office

12.456 Seminar in Rock Mechanics
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
______
Discussion of current research or advanced topics in continental tectonics, rock mechanics, or experimental structural geology.
B. Evans

12.458 Molecular Biogeochemistry
______

Not offered academic year 2017-2018Graduate (Fall)
(Subject meets with12.158)
Prereq: Permission of instructor
Units: 2-4-3 [P/D/F]
Lecture: T4-5.30 (E25-605)
______
Covers all aspects of molecular biosignatures, such as their pathways of lipid biosynthesis, the distribution patterns of lipid biosynthetic pathways with regard to phylogeny and physiology, isotopic contents, occurrence in modern organisms and environments, diagenetic pathways, analytical techniques and the occurrence of molecular fossils through the geological record. Students analyze in depth the recent literature on chemical fossils. Lectures provide background on the subject matter. Basic knowledge of organic chemistry required. Students taking graduate version complete additional assignments.
R. Summons
No required or recommended textbooks

12.460-12.461 Current Research in Geology and Geochemistry
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.460: TBA.
12.461: TBA.
______
Original investigations on problems in geology, petrology, mineralogy, geochemistry, or geobiology. 12.460 is letter-graded.
EAPS Staff
12.460: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.461: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.463 Geomorphology
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with12.163)
Prereq: 12.001, Physics I (GIR), Calculus I (GIR); or permission of instructor
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Quantitative examination of processes that shape Earth's surface. Introduction to fluvial, hillslope, and glacial mechanics. Essentials of weathering, soil formation, runoff, erosion, slope stability, sediment transport, and river morphology. Landscape evolution in response to climatic and tectonic forcing. Application of terrestrial theory to planetary surfaces. Additional instruction in geographic information systems (GIS) and remote sensing analysis, field measurement techniques, and numerical modeling of surface processes. Students taking the graduate version complete different assignments.
T. Perron

12.465 Sedimentology and Stratigraphy
______

Not offered academic year 2017-2018Graduate (Spring)
(Subject meets with12.110)
Prereq: Permission of instructor
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Studies sediments in the rock cycle; production of sediments at the Earth's surface; physics and chemistry of sedimentary materials; scale and geometry of near-surface sedimentary bodies, including aquifers; sediment transport and deposition in modern sedimentary environments; and burial and lithification. Surveys major sedimentary rock types. Also covers stratigraphic relationships of sedimentary basins, and evolution of sedimentary processes through geologic time. Includes two or three weekend days of field trips. Students taking graduate version complete additional assignments.
K. Bergmann

12.467 Seminar in Geomorphology
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
______
Discussion of current research or advanced topics in landscape evolution, surface hydrology, mechanics of sediment transport, basin analysis, or experimental geomorphology. Advanced instruction in process geomorphology.
EAPS Staff

12.470 Essentials of Geology
______

Graduate (Fall)
Not offered regularly; consult department
(Subject meets with12.170)
Prereq: Physics II (GIR), Calculus II (GIR); or permission of instructor
Units: 4-0-8
______
Geology of planetary interiors and surfaces, including plate tectonics, as a unifying theory of terrestrial geology, surface processes, and the Earth's interior. Igneous, metamorphic, and sedimentary processes associated with tectonic settings and the typical rock suites created. Mineral and rock identification. Causes of compositional differences on many scales: mineral grains, rocks, regions of the Earth, different planets. Conditions required for melting and melting processes. Rock structure and field techniques. Earth history. Treatment of these topics includes discussions of the geochemical, petrologic, geochronological, experimental, or field techniques used to investigate them; the limitations of current geological techniques and geological controversies; and great geological expeditions, experiments, and studies from the past, their premises, and their results. Students taking graduate version complete additional assignments.
EAPS Staff

12.471 Essentials of Geobiology
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: None
Units: 3-4-5
Lecture: MW9.30-11 (E25-605)
______
Introduces basic concepts of microbial structure, growth, energetics, molecular biology, and biochemistry. Presents examples of microbial interactions with environments throughout Earth's history as well as current topics in astrobiology. Includes lectures, discussions of literature, and a field trip. Lab focuses on student-designed projects that involve cultivation, modeling, or sample analyses. Intended for students whose background is not in biology, but who want to learn more about the contribution of microbes to geochemistry and planetary evolution.
T. Bosak
No textbook information available

12.473 Paleomagnetism and Planetary Magnetism
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 12.002, 18.03; or permission of instructor
Units: 2-0-4
Subject Cancelled Subject Cancelled
______
Introduces the study of natural remanent magnetization and the generation of planetary magnetic fields. Topics include paleomagnetism, rock magnetism, geomagnetism, magnetostratigraphy, paleomagnetic measurement techniques, polar wander and continental drift, biomagnetism, dynamo theory, and the history and evolution of magnetic fields on the Earth and planets.
B. P. Weiss

12.474 Origin and Evolution of the Earth's Crust
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
______
Broad overview of the origin and evolution of Earth's crust and mantle with emphasis on the study of the Precambrian rock record. Topics include: processes of crustal growth, stabilization, and reactivation; evaluation of secular change; and use of radiogenic isotopes in geochronology and as tracers of crust forming processes.
O. Jagoutz

12.475 Plate Tectonics and Continental Deformation
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
______
First half covers basic elements of plate tectonics, including sea floor spreading, magnetic anomalies, and subduction zone. Second half covers implications of plate tectonics for continental processes, including continental rifting, continental collision, and mountain building. Emphasis will be on correlating plate tectonic and continental processes using specific examples from around the world.
L. H. Royden

12.476 Radiogenic Isotope Geology
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-3-6
______
Applications of the variations in the relative abundance of radiogenic isotopes to problems of petrology, geochemistry, and tectonics. Topics: geochronology; isotopic evolution of Earth's crust and mantle; petrogenesis; and analytical techniques.
S. Bowring

12.480 Thermodynamics for Geoscientists
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 5.60 or 3.046
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Principles of thermodynamics are used to infer the physical conditions of formation and modification of igneous and metamorphic rocks. Includes phase equilibria of homogeneous and heterogeneous systems and thermodynamic modelling of non-ideal crystalline solutions. Surveys the processes that lead to the formation of metamorphic and igneous rocks in the major tectonic environments in the Earth's crust and mantle.
T. L. Grove

12.481 Advanced Field Geology I
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: 12.113, 12.114
Units: 2-2-2 [P/D/F]
Subject Cancelled Subject Cancelled
______
Introduction to the problems to be investigated in 12.482, as well as the regional setting and local geology of the field area. Various special techniques may be introduced and preparatory investigations may be conducted that are specific to the area to be studied in 12.482.
B. C. Burchfiel, O. Jagoutz

12.482 Advanced Field Geology II
______

Not offered academic year 2016-2017Graduate (IAP, Spring) Can be repeated for credit
Prereq: 12.481
Units arranged
______
In January, a geological and geomorphological study of a selected field area is conducted during a four-week excursion. The following term includes: preparation of maps and report based on field study conducted in January; and laboratory analysis of samples.
B. C. Burchfiel

12.484 Directed Field Studies
______

Graduate (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 0-6-0
______
Intensive training in field geological methods. Includes specific exercises selected to complement the backgrounds of the students enrolled and provides supervised experience in applying field analytical techniques to geological problems. Cannot be taken as a substitute for 12.115. Preference will be given to students associated with Course 12. Enrollment limited; students should apply early.
B. C. Burchfiel

12.485 Advanced Directed Field Studies
______

Graduate (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: 12.484
Units: 0-6-0
______
Continuation of 12.484. Designed to provide more advanced training in specific field geological methods. Can be taken during the same IAP period as 12.484. Preference will be given to students associated with Course 12. Enrollment limited; students should apply early.
Staff

12.486 Advanced Igneous Petrology
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-2-7
______
Comprehensive overview of igneous rocks from the Earth, Moon, and meteorite parent bodies. Discusses the compositional diversity of igneous rocks and how it can be used to elucidate rock forming processes in the major tectonic provinces on modern Earth, including mid-ocean ridges, subduction zones, ocean islands, and inter-continental rifting environments. Also covers magma generation processes in the terrestrial planets prior to 2.6 billion years ago. Laboratory exercises on selected suites of igneous rocks reinforce readings and classroom discussions. Uses evidence from related geo-science disciplines to develop an integrative approach to understanding processes that lead to the chemical differentiation of planetary bodies through time. Subject matter may be modified to reflect the interests of the group.
T. L. Grove

12.492 Fundamentals of Stable Isotope Fractionation
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: None
Units: 2-4-6
Subject Cancelled Subject Cancelled
______
Designed for bio-geo-chemists to gain a first order understanding of the origin of stable isotope effects and their application in understanding important geochemical processes on earth and planets. Includes an introduction of relevant physical chemistry, simple numerical integration methods of time-forward modeling to solve isotope systematics of complex systems, and discussion of the latest as well as classic papers of the topic.
S. Ono

12.493[J] Microbial Genetics and Evolution
______

Graduate (Fall)
(Same subject as1.87[J],7.493[J],20.446[J])
Prereq: 7.03, 7.05, or permission of instructor
Units: 4-0-8
Lecture: TR12.30-2.30 (66-160)
______
Covers aspects of microbial genetic and genomic analyses, central dogma, horizontal gene transfer, and evolution.
A. D. Grossman, G. Fournier
Textbooks (Fall 2016)

Geophysics

12.501 Essentials of Global Geophysics
______

Not offered academic year 2017-2018Graduate (Fall)
(Subject meets with12.201)
Prereq: Physics II (GIR), 18.03
Units: 4-0-8
URL: http://quake.mit.edu/~fjsimons/12.201-12.501.html
Lecture: MWF9 (54-824) +final
______
Overview of basic topics in solid-earth geophysics, such as the Earth's rotation, gravity and magnetic field, seismology, and thermal structure. Formulation of physical principles presented in three one-hour lectures per week. Current applications discussed in an additional one-hour tutorial each week. Students taking graduate version complete different assignments.
R. van der Hilst
No textbook information available

12.507 Essentials of Applied Geophysics
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with12.214)
Prereq: 18.03
Units: 3-3-6
______
Introduces the application of geophysical methods to all aspects of near-surface environmental and engineering geophysics, including the exploration for petroleum, water, and minerals. Topics include seismic, electrical, electromagnetic, ground penetrating radar, magnetics, gravity, rock physics and chemistry, borehole geophysics and the global positioning system (GPS). Uses a quantitative approach to emphasize basic principles and a physical /chemical understanding of each method. Discusses specific illustrative field examples. Lab work is mainly devoted to local field work and equipment preparation for the IAP Field Geophysics class. Students taking graduate version complete additional assignments.
F. D. Morgan, T. A. Herring, B. H. Hager

12.510 Introduction to Seismology
______

Graduate (Spring)
Prereq: 18.075 or 18.085
Units: 3-1-8
______
A basic study in seismology and the utilization of seismic waves for the study of Earth's interior. Introduces techniques necessary for understanding of elastic wave propagation in stratified media and for calculation of synthetic seismograms (WKBJ and mode summation). Ray theory; interpretation of travel times. (e.g., tomography); surface wave dispersion in layered media; Earth's free oscillations; and seismicity, (earthquake locations, magnitude, moment, and source properties).
G. Prieto

12.511 Field Geophysics
______

Not offered academic year 2016-2017Graduate (IAP)
(Subject meets with12.221)
Prereq: None
Units: 1-4-1 [P/D/F]
______
Covers practical methods of modern geophysics, including the global positioning system (GPS), gravity, and magnetics. Field work is conducted in western US and includes intensive 10-day field exercise. Focuses on measurement techniques and their interpretation. Introduces the science of gravity, magnetics, and the GPS. Measures crustal structure, fault motions, tectonic deformations, and the local gravity and magnetic fields. Students perform high-precision measurements and participate in data analysis. Emphasizes principles of geophysical data collection and the relevance of these data for tectonic faulting, crustal structure, and the dynamics of the earthquake cycle. Students taking graduate version complete additional assignments.
T. A. Herring, B. H. Hager, F. D. Morgan

12.512 Field Geophysics Analysis
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with12.222)
Prereq: 12.511
Units: 2-0-4
______
Focuses on in-depth data analysis and development of skills needed to report results both in writing and orally. Students use data collected in 12.511 to develop written and oral reports of the results, with each student focusing on a different area. For example, students can develop the geophysical modeling or synthesis of the results into other studies in the area. The final written and oral reports are combined into a comprehensive report and presentation of the field camp and its results. Students taking graduate version complete additional assignments.
T. A. Herring, B. H. Hager, F. D. Morgan

12.515 Data and Models
______

Graduate (Fall)
Prereq: 18.075 or 18.085
Units: 3-0-9
Lecture: TR3-4.30 (54-824)
______
Surveys a number of methods of inverting data to obtain model parameter estimates. Topics include review of matrix theory and statistics, random and grid-search methods, linear and non-linear least squares, maximum-likelihood estimation, ridge regression, stochastic inversion, sequential estimation, singular value decomposition, solution of large systems, genetic and simulated annealing inversion, regularization, parameter error estimates, and solution uniqueness and resolution. Computer laboratory and algorithm development.
F. D. Morgan
No textbook information available

12.520 Geodynamics
______

Graduate (Spring)
Prereq: 12.005; 18.075 or 18.085
Units: 3-0-9
______
Mechanics of deformation of the crust and mantle, with emphasis on the importance of different rheological descriptions: brittle, elastic, linear and nonlinear fluids, and viscoelastic.
B. H. Hager

12.521 Computational Geophysical Modeling
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces theory, design, and practical methods of computational modeling in geodynamics and geophysical fluid dynamics. Covers the most effective and widely used numerical modeling approaches (e.g., boundary element, finite difference, finite element) and emphasizes problem-solving skills through illustrative examples of heat and mass transfer in the mantle and the ocean. Students acquire experience with various numerical methods through regularly assigned computational exercises and a term-long modeling project of each student's choice.
J. Lin, O. Marchal, M. Behn

12.522 Geological Fluid Mechanics
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 8.03; 18.075 or 18.085
Units: 3-0-9
______
Treats heat transfer and fluid mechanics in the Earth, low Reynolds number flows, convection instability, double diffusion, Non-Newtonian flows, flow in porous media, and the interaction of flows with accreting and deforming boundaries. Applications include: the flow under plates, postglacial rebound, diapirism, magma dynamics, and the mantle convection problem.
J. A. Whitehead (WHOI)

12.524 Mechanical Properties of Rocks
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 8.03, 18.03
Units: 3-0-9
Lecture: M4-5.30 (54-611)
______
A survey of the mechanical behavior of rocks in natural geologic situations. Topics: brief survey of field evidence of rock deformation, physics of plastic deformation in minerals, brittle fracture and sliding, and pressure-solution processes. Results of field petrologic and structural studies compared to data from experimental structural geology.
B. Evans
No textbook information available

12.525 Mechanisms of Faulting and Earthquakes
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Explores the fundamental mechanics of faulting and earthquakes from four related perspectives: seismology, geodesy, geodynamics, and rheology. Topics to be covered include (1) the physical processes that control the rheology of faults, including friction and fracture, (2) how these rheological processes are manifest in faulting and earthquakes in the earth from a geodynamics perspective, and (3) how the mechanics of faulting and earthquakes are constrained by seismological and geodetic observations. Both continental and oceanic examples of faulting and earthquakes will be featured.
J. Lin, J. McGuire, Y. Liu

12.533 Rock Physics
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-3-6
______
Fundamentals of experimental and theoretical rock physics taught at an advanced level. Rocks viewed as complex composite media with behavior dependent both on the physical and chemical properties of the constituent phases, and on their geometries. Electrical, fluid transport, and seismic properties covered in detail. Other topics such as magnetic, mechanical, and thermal responses briefly discussed. Weekly laboratory.
F. D. Morgan

12.540 Principles of Global Positioning System
______

Graduate (Spring)
Prereq: Physics I (GIR), Calculus II (GIR), 18.06
Units: 3-1-8
______
The principles and applications of the Global Positioning System (GPS) and other space geodetic systems, including very-long-baseline interferometry (VLBI) and satellite laser ranging (SLR). The nature and uses of the course acquisition (CA), the precise positioning (P) codes, and the differential carrier phase observable. Techniques for estimating geodetic and geophysical quantities from these data. Other topics include: atmospheric refraction modeling, effects of Selective Availability (SA), estimation techniques (including Kalman filtering). Statistical and spectral analysis of data.
T. A. Herring

12.552 Advanced Seismology: Theory and Applications of Seismic Imaging
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 12.510
Units: 3-0-9
______
Introduces fundamental principles of seismic imaging used in both exploration and solid earth applications. Topics include ray theoretical approaches, scattering theory, and seismic waveform modeling. Through lectures, projects and student-led discussions of journal articles, the class covers the whole process of seismic imaging, from data preprocessing to model generation and geological interpretation of the results.
EAPS Faculty

12.560-12.561 Advanced Seminar in Exploration Geophysics
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
______
Advanced seminar focusing on areas of current interest in exploration geophysics and seismology. 12.560 is letter-graded.
Geophysics Staff

12.570 Topical Issues in Global Geophysics
______

Not offered academic year 2017-2018Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
______
Series of formal lectures and seminars with the specific content varying by term to reflect current issues in research. Meets jointly with relevant Harvard course.
R. D. van der Hilst

12.571 Seminar in Geophysics
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
Subject Cancelled Subject Cancelled
______
Problems of current interest in geophysics; subject matter varying from term to term.
Geophysics Staff

12.580-12.581 Current Research in Geophysics
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.580: TBA.
12.581: TBA.
______
Original investigations, laboratory work, or fieldwork in geophysics. 12.580 is letter-graded.
Geophysics Staff
12.580: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.581: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.586 Modeling Environmental Complexity
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with12.086)
Prereq: 18.03 or permission of the instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduction to mathematical and physical models of environmental processes. Emphasis on the development of macroscopic continuum or statistical descriptions of complex microscopic dynamics. Problems of interest include: random walks and statistical geometry of landscapes; percolation theory and transport in disordered media; fractals, scaling, and universality; ecological dynamics and the structure of ecosystems, food webs, and other natural networks; kinetics of biogeochemical cycles. Appropriate for advanced undergraduates. Beginning graduate students are encouraged to register for 12.586. Students taking the graduate version complete different assignments.
D. H. Rothman


left arrow|12.00-12.439 plus UROP, IND, TIP, ThU|12.440-12.599 plus ThG|12.600-12.999|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 12: Earth, Atmospheric, and Planetary Sciences
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Course 12: Earth, Atmospheric, and Planetary Sciences
Fall 2016


Planetary Science

12.601 Essentials of Planetary Science
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with12.420)
Prereq: 8.03, 18.03
Units: 3-0-9
______
Reviews fundamental physical concepts pertaining to the study of the solar system, and highlights recent spacecraft results. Topics include: meteorites, orbital dynamics, asteroids, impact craters, surfaces, atmospheres, atmospheric dynamics, interiors, magnetospheres, rings, comets, formation of the solar system.
B. P. Weiss

12.602 Asteroids and Small Bodies
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Physics II (GIR), 18.03
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduction to the study of asteroids and the ground-based and space-based techniques used to explore them. Topics include asteroid orbital properties, surface structure, physical properties, classifications, as well as their origin, thermal and collisional evolution, and interrelationships with meteorites and comets. Also covers the near-Earth asteroids, the probabilities and consequences of terrestrial collisions, and the possible utilization of asteroids as space resources.
R. P. Binzel

12.603 Solar System Dynamics
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Studies the dynamics of the solar system and its major subsystems, and the dynamics of exoplanets, with a modern emphasis on the qualitative structure of phase space. Topics may include rotational dynamics, spin-orbit coupling, Cassini states, and orbital dynamics, resonances, and Kozai oscillations, tidal evolution and tidal heating.
J. Wisdom

12.611 Advanced Planetary Observations
______

Graduate (IAP) Can be repeated for credit
Prereq: Permission of instructor
Units: 0-6-3 [P/D/F]
______
Individual research projects in planetary science and astrophysics involving supervised work at Lowell Observatory in Flagstaff, AZ. Projects may include observations made using Lowell's telescope facilities. Project topics and objectives vary from year to year. Written and oral reports required. Enrollment limited.
A. Bosh

12.620[J] Classical Mechanics: A Computational Approach
______

Graduate (Fall)
(Same subject as6.946[J],8.351[J])
Prereq: Physics I (GIR), 18.03, permission of instructor
Units: 3-3-6
Credit cannot also be received for12.008
URL: http://groups.csail.mit.edu/mac/users/gjs/6946/index.html
Lecture: MWF11 (54-819) Lab: W EVE (7-10 PM) (14-0637)
______
Classical mechanics in a computational framework, Lagrangian formulation, action, variational principles, and Hamilton's principle. Conserved quantities, Hamiltonian formulation, surfaces of section, chaos, and Liouville's theorem. Poincaré integral invariants, Poincaré-Birkhoff and KAM theorems. Invariant curves and cantori. Nonlinear resonances, resonance overlap and transition to chaos. Symplectic integration. Adiabatic invariants. Applications to simple physical systems and solar system dynamics. Extensive use of computation to capture methods, for simulation, and for symbolic analysis. Programming experience required. Students taking the graduate version complete additional assignments.
J. Wisdom, G. J. Sussman
Textbooks (Fall 2016)

12.625 Extrasolar Planets: Physics and Detection Techniques
______

Graduate (Fall)
(Subject meets with8.290[J],12.425[J])
Prereq: 8.03, 18.03
Units: 3-0-9
Lecture: TR1.30-3 (54-824)
______
In-depth study of current topics in exoplanets, such as exoplanet transits, radial velocity curves, current survey missions, the mass-radius relation, and super Earths. Class activities consist of reading the current literature, problem sets, and a term project. Students taking graduate version complete additional assignments.
S. Seager
No textbook information available

12.650 Current Topics in Planetary Science
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
In-depth discussion of current and classic literature on selected topics in planetary science. Topics vary from year to year.
J. Wisdom

12.652 Current Topics in Planetary Science
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9 [P/D/F]
______
In-depth discussion of current and classic literature on selected topics in the specialty areas of asteroids and the Pluto-Charon system. Topics vary from year to year.
R. P. Binzel

12.690-12.691 Current Research in Planetary Science
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.690: TBA.
12.691: TBA.
______
Original investigations, laboratory work, or fieldwork in planetary science. 12.690 is letter-graded.
Planetary Science Staff
12.690: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.691: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

Geological, Geophysical, and Chemical Oceanography

12.701 Classic Papers in Physical Oceanography
______

Graduate (Spring)
Prereq: None
Units: 3-0-3 [P/D/F]
______
Provides a historical perspective on fundamental topics in oceanography by considering individual works which, when pieced together, contribute to the more cohesive description of how the ocean works. In class discussions, students consider various aspects of the work in question, including motivation, approach, and implications for the broader context. They also synthesize information and make oral presentations. Develops basic analytical and critical skills in paper reading and writing.
Y. Kwon (WHOI)

12.702 Elements of Modern Oceanography
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
TBA.
______
Examines a series of crosscutting topics that exemplify current directions in interdisciplinary oceanography. Focuses on current themes in oceanography, their inter-disciplinary nature, and the role of ocean sciences in society. Introduces core concepts across the disciplines of biological, physical, and chemical oceanography as well as marine geology. Emphasis on the inter-disciplinary aspects of these core concepts, the kinds of approaches and modes of thinking common to all of the disciplines, and the technological developments underpinning current advances.
G. Lawson, A. Kirincich (WHOI)
No textbook information available

12.703 Presenting Scientific Research
______

Graduate (Fall)
Prereq: None
Units: 3-0-3
TBA.
______
Presenting scientific research geared toward a scientific audience. Each student gives one 30-minute talk, one AGU-style 15-minute talk, and one poster presentation. Students present their ongoing research and use the class as a forum to practice for upcoming talks in more formal settings. Abstracts are prepared for each presentation and discussed in class. Students provide comments, questions, encouragement, critiques, etc. on their peers' presentations.
S. Nielsen, V. Le Roux (WHOI)
No textbook information available

12.707 The History of Earth's Climate
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Climate history of the Earth from the formation of the early atmosphere and ocean to the present. Evaluation of geochemical, sedimentological, and paleontological evidence for changes in ocean circulation, global temperatures, and atmospheric carbon dioxide levels. Theories and models of Phanerozoic climate change. Long-term history of the global carbon cycle.
D. McGee

12.708 Seminar in Paleoclimatology
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Advanced seminar focusing on areas of current interest in paleoceanography and paleoclimatology. Includes discussion of current and classic literature. Topics vary from year to year.
D. Oppo, O. Marchal (WHOI)
No textbook information available

12.710 Geological Oceanography
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
TBA.
______
Provides a high level survey of a broad range of active science topics in Geological Oceanography. Presents background material that graduate students are expected to know in the disciplines of solid-earth geophysics, geochemistry, sedimentology and stratigraphy, coastal processes, and climate, including a representative set of canonical science papers, and builds on this material to give a sense of the current state of the science in these fields. Broad topics include the formation of the earth, petrogenesis, volcanism, plate tectonics, geodynamics, sedimentation in the oceans, coastal morphodynamics, paleo-oceanography, and climate. The interconnectedness of and feedbacks between processes discussed under these various topics is emphasized.
WHOI Staff
No textbook information available

12.712 Advanced Marine Seismology
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-6
______
Focuses on synthetic seismograms, ocean bottom refraction seismology, and multi-channel reflection seismology as applied to studies of the ocean sediments, crust, and lithosphere. Topics include: the wave equations for elastic/anelastic, isotropic/anisotropic, homogeneous/heterogeneous and fluid/solid media; ray theory and WKBJ approximations; the Sommerfeld/Weyl integrals, asymptotic analysis, and Lamb's problem for a fluid/solid interface; reflectivity and related methods; finite difference and finite element methods; and special topics of interest to the class. Extensive readings of geophysical and seismological literature.
R. Stephen (WHOI)

12.714 Computational Data Analysis
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.03
Units: 3-0-9
______
An introduction to the theory and practice of analyzing discrete data such as are normally encountered in geophysics and geology. Emphasizes statistical aspects of data interpretation and the nonparametric discrete-time approach to spectral analysis. Topics include: elements of probability and statistics, statistical inference, robust and nonparametric statistics, the method of least squares, univariate and multivariate spectral analysis, digital filters, and aspects of multidimensional data analysis.
A. D. Chave, T. A. Herring

12.716 Essentials of Oceanic Petrology
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: 12.710 or permission of instructor
Units: 3-2-4
Subject Cancelled Subject Cancelled
______
Qualitative interpretation and quantitative analysis of melting, melt transport, melt-rock reactions, igneous crustal accretion, metamorphism and hydrothermalism at oceanic spreading centers and subduction-related arcs applied to understanding the variations in the composition of the Earth's (oceanic) mantle and crust and accretionalry processes at mid-ocean ridges. Combines theoretical methods with field, petrographic, geochemical, and computational techniques. Topics vary from year to year.
H. Dick, F. Klein, V. Le Roux (WHOI)

12.717 Coastal Geomorphology
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Explores mechanisms behind the formation and reshaping of coastal environments. Focuses on a process-based understanding of both the fluid dynamic and sediment transport aspects of coastal landforms, and, especially, the importance of feedbacks between the two. Investigates coastal evolution at various scales - from ripples to coastline formation - with an emphasis on the behavior of coastal environments over integrated timescales of days and years to centuries and millennia. Students investigate the effect of storms, sea-level rise, and interactions with biological and anthropogenic influences. Covers a broad array of coastal environments, including beaches, barrier islands, spits, inlets, tidal flats, deltas, rocky coasts, arctic shores, and carbonate atolls.
A. Ashton

12.718 Kinetics and Mass Transport
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
______
Offers a broad overview of various kinetic and transport processes in geology, including volume and grain boundary solid-state diffusion, defects in minerals, rates of mineral reaction and transformation, crystal nucleation and growth, advective transport in porous media and partially molten aggregates, and percolation theory. Emphasis on processes in crystalline rocks. Covers theoretical, phenomenological, and experimental constraints, with a consistent application to "real-world" settings and actual case histories.
M. Behn and G. Gaetani (WHOI)

12.721 Current Research in Marine Geology and Geophysics at Woods Hole
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Original investigations, laboratory work, or fieldwork in marine geology and geophysics.
WHOI Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.722 Current Research in Chemical Oceanography at Woods Hole
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Original investigations, laboratory work, or fieldwork in chemical oceanography.
WHOI Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.730-12.731 Current Research in Marine Geology and Geophysics at MIT
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.730: TBA.
12.731: TBA.
______
Original investigations, laboratory work, or fieldwork in marine geology and geophysics under the supervision of a faculty member in residence at MIT. For students in the MIT/WHOI Joint Program. 12.730 is letter-graded.
Marine Geology and Geophysics Staff
12.730: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.731: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.735-12.736 Current Research in Chemical Oceanography at MIT
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.735: TBA.
12.736: TBA.
______
Original investigations, laboratory work, or fieldwork in chemical oceanography under the supervision of a faculty member in residence at MIT. For students in the MIT/WHOI Joint Program. 12.735 is letter-graded.
Chemical Oceanography Staff
12.735: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.736: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.739 Marine Microbiology and Biogeochemistry
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: None
Units: 3-0-9
______
Integrates the fields of microbiology and biogeochemistry, and is centered on elucidating the linkages between microorganisms and geochemical processes in the oceans. Divided into modules that first lay the theoretical framework to familiarize students of diverse backgrounds (biologists, chemists, physical oceanographers). Next, introduces specific and general linkages between the topics and the major tools and techniques that have advanced their integrated study. Concludes with a synthesis module examining the role of microorganisms in the biogeochemical cycles of diverse ocean biomes
A. Apprill, S. Sievert (WHOI)

12.740 Paleoceanography
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Studies the basic principles of techniques for reconstructing the history of ocean climate from marine sediment cores, corals, ice cores, and other paleoclimate archives. Examines this data in the light of proposed climate change mechanisms. Micropaleontological, isotopic, geochemical, and mineralogical changes are used to infer changes in seawater composition, atmospheric chemistry, and climate. Observations are interpreted as consequences of changes in ocean temperature, circulation, and chemistry, and are used to evaluate theories proposed to account for glacial/interglacial cycles. Focuses on the past two million years, but major processes and events from the past 100 million years are also included.
E. A. Boyle

12.741 Marine Bioinorganic Chemistry
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of Instructor
Units: 2-0-7
______
Provides an overview of trace element biogeochemistry and marine bioinorganic chemistry. Topics include controls on oceanic trace metal distributions; co-evolution of biological metal requirements and metal availability during early Earth history; chemical speciation and its influence on microbial bioavailability; applications of metal isotopes; roles of metalloenzymes and metal proteins in biogeochemical cycles; and biogeochemical applications of metagenomics, metaproteomics, and bioinformatics.
M. Saito

12.742 Marine Chemistry
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
And clark 271 at WHOI. TBA.
______
An introduction to chemical oceanography. Reservoir models and residence time. Major ion composition of seawater. Inputs to and outputs from the ocean via rivers, the atmosphere, and the sea floor. Biogeochemical cycling within the oceanic water column and sediments, emphasizing the roles played by the formation, transport, and alteration of oceanic particles and the effects that these processes have on seawater composition. Cycles of carbon, nitrogen, phosphorus, oxygen, and sulfur. Uptake of anthropogenic carbon dioxide by the ocean. Material presented through lectures and student-led presentation and discussion of recent papers.
B. Van Mooy, S. Doney (WHOI)
No textbook information available

12.743 Geochemistry of Marine Sediments
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Chemistry (GIR), 5.60
Units: 3-0-9
______
Focuses on processes that control the composition of sediments in coastal, shelf, and deep-sea environments and processes that define their roles in biogeochemical cycles. Topics include calculating chemical fluxes across the sediment-water interface; evaluating the sources and reactivity of carbonate, silicic, and detrital sediments; using pore water gradients to calculate diffusion, reaction, and flux rates; sediment dating; estimating accumulation rates; and using stable isotopes and natural-series radioisotopes. Covers evaluation of the links between sedimentary and water column processes; the effects of anthropogenic disturbances (e.g., eutrophication, acidification, warming) on sedimentary processes; and the role of sediments in global biogeochemical cycles. Introduces sampling techniques and mathematical modeling of sedimentary processes.
D. McCorkle, W. Martin, A. Spivak (WHOI)

12.744 Marine Isotope Chemistry
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of the instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Fundamentals of using isotopes to study processes and timescales for marine chemistry and geochemistry. Starts with a basic introduction to the nature, origins, and reasons for the distributions of isotopes in nature, then develops theory and approaches for radioactive dating methods. These are used to constrain the timing and nature of the geochemical evolution of the elements, solar system, earth, ocean and atmosphere. Cosmogenic isotopes and their applications are covered. Basics of mass spectrometry are briefly discussed, and then the principles and applications of isotope fractionation are more thoroughly dealt with. Introduction to mass independent fractionation and clumped isotope methods. Explores applications of isotope methods to a number of water column processes, including particle scavenging, sedimentation, long term element budgets, redox processes, and air-sea exchange. Emphasis will be on quantitative methods and problem-solving, and there will be four problem sessions with development of problem solutions.
WHOI Staff

12.746 Marine Organic Geochemistry
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Provides an understanding of the distribution of organic carbon (OC) in marine sediments from a global and molecular-level perspective. Surveys the mineralization and preservation of OC in the water column and within anoxic and oxic marine sediments. Topics include: OC composition, reactivity and budgets within, and fluxes through, major reservoirs; microbial recycling pathways for OC; models for OC degradation and preservation; role of anoxia in OC burial; relationships between dissolved and particulate (sinking and suspended) OC; methods for characterization of sedimentary organic matter; application of biological markers as tools in oceanography. Both structural and isotopic aspects are covered.
D. Repeta, T. I. Eglinton (WHOI)

12.747 Modeling, Data Analysis, and Numerical Techniques for Geochemistry
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
TBA.
______
Emphasizes the basic skills needed for handling and assimilating data as well as the basic tool-set for numerical modeling. Uses MATLAB as its computation engine; begins with an introduction to MATLAB to ensure familiarity with software. Topics include: probability distributions, error propagation, least squares and regression techniques, principle component and factor analysis, objective mapping, Fourier and spectral analysis, numerical solutions to ODEs and PDEs, finite difference techniques, inverse models, and scientific visualization.
D. Glover, W. Jenkins, S. Doney (WHOI)
No textbook information available

12.749 Solid Earth Geochemistry
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Integrates methods in mineralogy, petrology (both igneous and metamorphic), and trace element and isotope geochemistry to address scientific issues of the solid earth. Covers processes in the solar nebula, accretion, and early differentiation of the earth. Discusses topics in three representative geodynamic environments - mid-ocean ridges, subduction zones, and mantle plumes - with respect to physical framework and petrological/geochemical aspects.
N. Shimizu, S. Nielsen (WHOI)

12.751-12.759 Seminar in Oceanography at Woods Hole
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.754: TBA.
Subject Cancelled 12.757 Cancelled
______
Topics in marine geology and geophysics, physical, dynamical, and chemical oceanography. Content varies from term to term. 12.754, 12.755, and 12.756 are letter-graded.
WHOI Staff
12.754: No textbook information available

12.760-12.761 Seminar in Marine Geology and Geophysics at MIT
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Topics in marine geology and geophysics taught at MIT. Content varies from term to term. 12.760 is letter-graded.
Marine Geology and Geophysics Staff

12.770-12.771 Seminar in Chemical Oceanography at MIT
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Topics in chemical oceanography taught at MIT. Content varies from term to term. 12.770 is letter-graded.
Chemical Oceanography Staff

Atmospheres, Oceans, and Climate

12.800 Fluid Dynamics of the Atmosphere and Ocean
______

Graduate (Fall)
Prereq: 8.03, 18.04
Units: 3-0-9
MIT and clark 331 at WHOI. Lecture: MW9-10.30 (54-1623) +final
______
Introduction to fluid dynamics. Students acquire an understanding of some of the basic concepts of fluid dynamics that are needed as a foundation for advanced courses in atmospheric science, physical oceanography, ocean engineering, climate science, etc. Emphasizes fluid fundamentals, with an atmosphere/ocean twist.
J. Marshall
Textbooks (Fall 2016)

12.801 Large-scale Ocean Dynamics
______

Graduate (Spring)
Prereq: 12.800
Units: 3-0-9
______
Applies fundamental principles of geophysical fluid dynamics to understand the general patterns of the ocean circulation and stratification. Includes the mid-latitude wind-driven circulation, the Southern Ocean circulation, and the global overturning circulation. Uses a combination of theory, numerical simulations, and observations to illustrate the concepts.
R. Ferrari

12.802 Small-scale Ocean Dynamics
______

Graduate (Spring)
Prereq: 12.800
Units: 3-0-9
______
Basic ideas of geophysical wave motion in rotating, stratified, and rotating-stratified fluids. Subject begins with general wave concepts of phase and group velocity. The dynamics and kinematics of gravity waves with a focus on dispersion, energy flux, initial value problems, etc. Subject foundation used to study internal and inertial waves, Kelvin, Poincare, and Rossby waves in homogeneous and stratified fluids. Laplace tidal equations are applied to equatorial waves. Other topics include: resonant interactions, potential vorticity, wave-mean flow interactions, and instability.
G. Flierl and P. O'Gorman

12.805 Data Analysis in Physical Oceanography
______

Graduate (Spring)
Prereq: 12.808
Units: 3-0-6
______
Introduction to standard data analysis methods, including time series analysis, objective mapping, and empirical orthogonal functions. Focuses on working with data in a computer laboratory setting. Emphasizes how statistical information can be used to improve experimental design. Some attention given to the instruments and algorithms used to acquire the data.
G. Gebbie

12.806[J] Atmospheric Physics and Chemistry
______

Graduate (Spring)
(Same subject as10.571[J])
(Subject meets with12.306)
Prereq: 5.60 or 5.61; 18.075; or permission of instructor
Units: 3-0-9
______
Introduction to the physics and chemistry of the atmosphere including experience with computer codes. Aerosols and theories of their formation, evolution, and removal. Gas and aerosol transport from urban to continental scales. Coupled models of radiation, transport, and chemistry. Solution of inverse problems to deduce emissions and removal rates. Emissions control technology and costs. Applications to air pollution and climate.
R. G. Prinn

12.807[J] Atmospheric Chemistry
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as1.84[J], 10.817[J])
Prereq: 5.60
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Provides a detailed overview of the chemical transformations that control the abundances of key trace species in the Earth's atmosphere. Emphasizes the effects of human activity on air quality and climate. Topics include photochemistry, kinetics, and thermodynamics important to the chemistry of the atmosphere; stratospheric ozone depletion; oxidation chemistry of the troposphere; photochemical smog; aerosol chemistry; and sources and sinks of greenhouse gases and other climate forcers.
J. H. Kroll

12.808 Introduction to Observational Physical Oceanography
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
TBA.
______
Results and techniques of observations of the ocean in the context of its physical properties and dynamical constraints. Emphasis on large-scale steady circulation and the time-dependent processes that contribute to it. Includes the physical setting of the ocean, atmospheric forcing, application of conservation laws, description of wind-driven and thermohaline circulation, eddy processes, and interpretive techniques.
M. Andres, G. Gebbie (WHOI)
No textbook information available

12.809 Hydraulic Phenomena in Geophysical Fluid Flows
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
______
Examination of the hydraulics of nonrotating flows (Long's experiments, hydraulic control, upstream influence, nonlinear wave steepening, hydraulic jump and bores, application to severe downslope winds). Other topics may include: nonrotating stratified flows (two-layer hydraulics, virtual and approach controls, maximal and submaximal flow, application to the Strait of Gibraltar and the Bab al Mandab); and deep ocean straits and sills (steady theories for rotating channel flow, nonlinear Kelvin and frontal waves, rotating hydraulic jumps, geostrophic adjustment in a rotating channel, and applications to the Denmark Strait and other deep passages).
L. Pratt, K. Helfrich (WHOI)

12.810 Dynamics of the Atmosphere
______

Graduate (Spring)
Prereq: 12.800
Units: 3-0-9
URL: http://www.mit.edu/~pog/810.html
______
Discusses the dynamics of the atmosphere, with emphasis on the large scale. Topics include zonally symmetric circulations and the tropical Hadley circulation; internal gravity waves; balanced flows, potential vorticity conservation and Rossby waves; stability of zonal flows; baroclinic instability and extratropical storms; tropical waves, the Walker circulation, and El Niño and the Southern Oscillation; and the role of eddies in the general circulation. Students taking graduate version complete different assignments.
R. A. Plumb

12.811 Tropical Meteorology
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 12.810 orCoreq: 12.843
Units: 3-0-9
______
A description of the large-scale circulation systems of the tropical atmosphere and analysis of the dynamics of such systems. Topics include: Radiative-convective equilibrium; the Hadley and walker circulation; monsoons; tropical boundary layers; theory of the response of the tropical atmosphere to localized sea-surface temperature anomalies; intraseasonal oscillations; equatorial waves; El Niño/Southern Oscillation; easterly waves; and tropical cyclones.
K. A. Emanuel

12.812 The General Circulation of the Atmosphere and Climate Change
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 12.843 or permission of instructor
Units: 3-0-9
______
Explains the main features of the general circulation of the Earth's atmosphere. Final part of the course explores possible changes in the general circulation associated with climate change.
P. O'Gorman

12.814[J] Aerosol and Cloud Microphysics and Chemistry
______

Graduate (Spring)
(Same subject as1.842[J])
(Subject meets with12.338)
Prereq: Permission of instructor
Units: 3-0-9
______
Focuses on understanding how aerosol particles form droplets or ice crystals during several atmospheric processes: determining Earth's radiative balance; heterogeneous chemistry and acid rain; understanding where, when and how much precipitation occurs. Provides tools for understanding the physics of aerosol and cloud element motion; the interaction of particles with water vapor, including phase changes and droplet and ice nucleation; the chemical composition of particles and the effect on cloud formation processes; and the effect of cloud processing on aerosol chemistry. Discusses relevant topics of contemporary interest, e.g., geoengineering and weather modification and volcanic effects. Students taking the graduate version complete different assignments.
D. Cziczo

12.815 Atmospheric Radiation and Convection
______

Graduate (Fall)
Prereq: 5.61, 12.800, 18.075, or permission of instructor
Units: 5-2-5
Lecture: MW10.30-12 (54-824)
______
Introduction to the physics of atmospheric radiation, remote sensing, and convection, including use of computer codes. Radiative transfer equation including emission and scattering, spectroscopy, Mie theory, and numerical solutions. Physics of dry and moist convection, including moist thermodynamics. Radiative-convective equilibrium. Solution of inverse problems in remote sensing of atmospheric temperature and composition.
T. Cronin
Textbooks (Fall 2016)

12.817[J] Atmospheric Composition in the Changing Earth System
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as1.841[J])
Prereq: 1.84
Units: 3-0-9
______
Explores how atmospheric chemical composition both drives and responds to climate, with a particular focus on feedbacks via the biosphere. Topics include atmospheric nitrogen; DMS, sulfate, and CLAW; biogenic volatile organic compounds and secondary organic aerosol; wildfires and land use change; atmospheric methane and the oxidative capacity of the troposphere; and air quality and climate and geoengineering.
C. Heald

12.818 Introduction to Atmospheric Data and Synoptic Meteorology
______

Graduate (Fall)
Prereq: None.Coreq: 12.800
Units: 3-3-6
Lecture: TR12-1.30 (54-1623)
______
Provides a general introduction to meteorological data and analysis techniques, and their use in the MIT Synoptic Laboratory to study the phenomenology and dynamics of large-scale atmospheric flow. Balance concepts as applied to the dynamics of frontal and synoptic scales are illustrated using real-time upper air and surface station data and gridded analyzed fields. Advanced meteorological software packages are used to access, manipulate, and graphically display the data.
L. Illari
No textbook information available

12.820 Turbulence in the Ocean and Atmosphere
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 12.843
Units: 3-0-9
______
Covers phenomena, theory and modeling of turbulence in the Earth's oceans and atmosphere. The scope will range from centimeter- to planetary-scale motions. Includes homogeneous isotropic three- and two-dimensional turbulence, convection, stratified turbulence, quasi-gesotrophic turbulence, baroclinic turbulence, and macroturbulence in the ocean and atmosphere.
R. Ferrari, G. Flierl

12.823 Modeling the Biology and Physics of the Ocean
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 18.075 or 18.085
Units: 3-0-6
______
Principles and examples of the construction of physical/ biological models for oceanic systems. Individual-based and continuum representations. Food webs and structured population models. Fluid transport, stirring, and mixing. Effects of rotation and stratification. Advection, diffusion, reaction dynamics. Oceanic examples of physical-biological dynamics: surface mixed layer, upwelling regimes, mesoscale eddies, and oceanic gyres.
G. Flierl, D. McGillicuddy

12.824 Stability Theory for Oceanic & Atmospheric Flows
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 12.802 or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Basic theory of hydrodynamic instability with special application to flows of interest in oceanography and meteorology. Topics covered include general formulation of stability theory; concept of normal modes and linearization; fundamental stability theorems; baroclinic instability: Charney model, Eady model and the Phillips two-layer model; energy transformations; initial value theory and non-modal instability; barotropic instability for jets and shear layers; radiating instabilities; initial value problems applied to the concepts of convective, absolute and spatial instabilities; finite amplitude theory; stability of non-parallel flows.
G. Flierl

12.830 Topics in Waves and Instability
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 12.843
Units: 3-0-9
______
A detailed presentation of selected advanced topics in waves and instability in the atmosphere. The precise selection varies from year to year. Topics have included wave-mean flow interaction, the quasi-biennial oscillation, sudden warmings, critical-level behavior, wave overreflection, nonlinear equilibration, wave breaking, tropical waves, and stationary waves.
EAPS Staff

12.835 Experimental Atmospheric Chemistry
______

Graduate (Fall)
(Subject meets with12.335)
Prereq: Permission of instructor
Units: 2-4-6
Lecture: TR1.30-3 (54-1623)
______
Introduces the atmospheric chemistry involved in climate change, air pollution, and ozone depletion using a combination of interactive laboratory and field studies and simple computer models. Uses instruments for trace gas and aerosol measurements and methods for inferring fundamental information from these measurements. Students taking the graduate version complete different assignments.
R. Prinn, S. Ono, K. Dryer
No required or recommended textbooks

12.842 Climate Science
______

Graduate (Fall)
(Subject meets with12.301)
Prereq: Chemistry (GIR), 18.03, or permission of instructor
Units: 4-0-8
Lecture: MWF2 (54-824)
______
Introduction to climate studies, including beginnings of the solar system, time scales, and climate in human history; methods for detecting climate change, including proxies, ice cores, instrumental records, and time series analysis; physical and chemical processes in climate, including primordial atmosphere, ozone chemistry, carbon and oxygen cycles, and heat and water budgets; internal feedback mechanisms, including ice, aerosols, water vapor, clouds, and ocean circulation; climate forcing, including orbital variations, volcanism, plate tectonics, and solar variability; climate models and mechanisms of variability, including energy balance, coupled models, and global ocean and atmosphere models; and outstanding problems. Students taking the graduate version complete different assignments.
K. Emanuel, E. Boyle, D. McGee
Textbooks (Fall 2016)

12.843 Large-scale Atmosphere and Ocean Dynamics
______

Graduate (Fall)
Prereq: 12.801, 12.810, or permission of instructor
Units: 2-4-9
Lecture: WF1 (54-823) Lab: MR3-5 (54-1527) Recitation: M1 (54-823)
______
Project-based with lectures covering the relevant theory. Students work in groups on four projects. Each of these comprises a numerical part, to illuminate and illustrate the theory, and a data part (drawn from laboratory tank experiments, atmospheric, or ocean observations), to illustrate the phenomena. Topics include: barotropic vorticity dynamics including inversion and evolution, geostrophic and higher order balance, baroclinic dynamics and the evolution of balanced flows, and stability with emphasis on the mutual interaction of disturbances. Projects include a verbal presentation and writeup covering both the numerical and geophysical parts plus additional derivations as needed.
G. Flierl, L. Illari
No required or recommended textbooks

12.844[J] Modeling and Assessment for Policy
______

Graduate (Spring)
(Same subject asIDS.410[J])
Prereq: None
Units: 3-0-6
______
Explores how scientific information and quantitative models can be used to inform policy decision-making. Develops an understanding of quantitative modeling techniques and their role in the policy process through case studies and interactive activities. Addresses issues such as analysis of scientific assessment processes, uses of integrated assessment models, public perception of quantitative information, methods for dealing with uncertainties, and design choices in building policy-relevant models. Examples focus on models and information used in Earth system governance.
N. E. Selin

12.845[J] Sustainability Science and Engineering
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject asIDS.526[J])
Prereq: None
Units: 3-0-6
______
Introduces and develops core ideas and concepts in the field of sustainability science and engineering from an engineering systems perspective. Takes an interdisciplinary approach to discuss case studies of sustainability systems research. Exposes students to techniques for sustainability research across engineering, natural and social science disciplines. Term projects focus on applying techniques.
N. E. Selin

12.846[J] Global Environmental Negotiations
______

Graduate (Fall)
(Same subject asIDS.525[J])
(Subject meets with12.346[J],IDS.062[J])
Prereq: None
Units: 2-0-4
Lecture: T2.30-4.30 (4-144)
______
Practical introduction to global environmental negotiations designed for science and engineering students. Covers basic issues in international negotiations, such as North-South conflict, implementation and compliance, trade, and historical perspective on global environmental treaties. Offers hands-on practice in developing and interpreting international agreements through role-play simulations and observation of ongoing climate change negotiating processes. Students taking graduate version complete additional assignments.
N. Selin
Textbooks (Fall 2016)

12.848[J] Global Climate Change: Economics, Science, and Policy
______

Graduate (Spring)
(Same subject as15.023[J])
(Subject meets with12.348[J],15.026[J])
Prereq: Calculus II (GIR); 5.60; 14.01 or 15.010; or permission of instructor
Units: 3-0-6
______
Introduces scientific, economic, and ecological issues underlying the threat of global climate change, and the institutions engaged in negotiating an international response. Develops an integrated approach to analysis of climate change processes, and assessment of proposed policy measures, drawing on research and model development within the MIT Joint Program on the Science and Policy of Global Change. Graduate students are expected to explore the topic in greater depth through reading and individual research.
R. G. Prinn

12.849 Mechanisms and Models of the Global Carbon Cycle
______

Graduate (Spring)
(Subject meets with12.349)
Prereq: Permission of instructor
Units: 3-0-9
______
Addresses changes in the ocean, terrestrial biosphere and rocks modulation of atmospheric carbon dioxide on timescales from months to millions of years. Includes feedbacks between carbon cycle and climate. Combines hands-on data analysis with the formulation of simple models rooted in basic physical, chemical and biological principles. Students create individual "toy" global carbon cycle models. Students taking graduate version complete different assignments.
M. Follows

12.850 Computational Ocean Modeling
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: None
Units: 3-0-9
______
Numerical modeling in oceanography and environmental fluid mechanics. Focuses on the building of computational models that describe processes such as transport (advection, diffusion), reaction (ecosystems), and boundary forcing, of relevance in the ocean. Models are developed in a hierarchical manner, starting from the simple (zero-dimensional in space), and incrementally advancing toward more complex, time-evolving systems in one-, two- (shallow water) and three-dimensions (Primitive equations). Students build their own models using the finite volume approach with an appreciation and understanding of the working of general circulation models
A. Mahadevan (WHOI)

12.853 Advanced geophysical fluid dynamics
______

Graduate (Fall)
Prereq: 12.843 or permission of instructor
Units: 2-0-7
TBA.
______
Follow-on to 12.843, with a more mathematical treatment and extension of material to current topics of interest involving rotating, stratified flows of oceans and atmospheres.
G. Flierl
No textbook information available

12.860 Climate Variability and Diagnostics
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Practical insight into characteristics and mechanisms of climate variability from regional to global scale in the modern world with applications to past and future climates. Major emphasis is placed on the salient features of the mean climate system and their dominant modes of natural variability (e.g., El Nino-Southern Oscillation, North Atlantic Oscillation) as well as observed and projected manifestations of anthropogenic climate change. Learning is driven by exploration of data and supplemented by lectures and published literature. Through inter-active learning students gain experience accessing and analyzing a wide range of gridded data including instrumental, satellite, and reanalysis products as well as IPCC global climate model simulations.
C. Uhmmenhofer

12.862 Coastal Physical Oceanography
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 12.800
Units: 3-0-9
TBA.
______
Introduction to the dynamics of flow over the continental shelf, nearshore, and estuaries, emphasizing both theory and observations. Content varies somewhat according to student and staff interests. Possible topics include fronts, buoyant plumes, surface and bottom boundary layers, wind-driven upwelling, coastal-trapped waves, internal waves, quasi-steady flows, high-latitude shelf processes, tides, and shelf-open ocean interactions.
R. Todd, D. Ralston (WHOI)
No textbook information available

12.863 Advanced Topics in Coastal Physical Oceanography
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 12.862 or permission of instructor
Units: 3-0-6
______
More specialized topics in the dynamics of flow over the continental shelf, including coastal-trapped waves, wind-driving, and mean flows. Emphasis on the relationship between theory and observations. Instrumentation and the application of statistical techniques also covered.
Woods Hole Staff

12.866 Theory of the General Circulation of the Ocean
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 12.800, 12.801, 12.802
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
A review of wind-driven circulation, and the development of the baroclinic theory of the wind-driven circulation. Potential vorticity homohenization and the ventilated thermocline. Wind-driven circulation with continuous stratification, subduction/obduction. Equatorial thermocline and its relation to ENSO. Decadal climate variability. Thermohaline circulation and variability. Abyssal circulation. Mixing and energetics of the oceanic general circulation.
R. X. Huang (WHOI)

12.870 Air-Sea Interaction: Boundary Layers
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Graduate-level fluid mechanics and a subject on waves, or permission of instructor
Units: 3-0-9
TBA.
______
Addresses the interaction of the atmosphere and ocean on temporal scales from seconds to days and spatial scales from centimeters to kilometers. Topics include the generation, propagation, and decay of surface waves; the processes by which mass, heat, momentum, and energy are transported vertically within the coupled atmospheric and oceanic boundary layers and across the air-sea interface; and the statistical tools, mathematical models, and observational methods that are used to quantify these processes.
J. Trowbridge, E. Terray (WHOI)
No textbook information available

12.885[J] Science, Politics, and Environmental Policy
______

Graduate (Fall)
(Same subject as11.373[J])
(Subject meets with12.385)
Prereq: Permission of instructor
Units: 3-0-6
Lecture: M EVE (3-6 PM) (54-1623)
______
Examines the role of science in US and international environmental policymaking. Surveys the methods by which scientists learn about the natural world; the treatment of science by experts, advocates, the media, and the public and the way science is used in legislative, administrative and judicial decision making. Through lectures, group discussions, and written essays, students develop a critical understanding of the role of science in environmental policy. Potential case studies include fisheries management, ozone depletion, global warming, smog, and endangered species. Students taking the graduate version complete different assignments.
S. Solomon, J. Knox-Hayes
No required or recommended textbooks

12.950, 12.951 Seminar in Physical Oceanography at MIT
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Topics in physical and dynamical oceanography. Content varying from term to term. 12.950 is letter-graded.
Physical Oceanography Staff

12.960, 12.961 Current Research in Physical Oceanography at MIT
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.960: TBA.
12.961: TBA.
______
Original investigations, laboratory work, or fieldwork in oceanography. 12.960 is letter-graded.
Physical Oceanography Staff
12.960: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.961: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.970, 12.971 Current Research in Physical Oceanography at Woods Hole
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.970: TBA.
12.971: TBA.
______
Original investigations, laboratory work, or field work on oceanographic problems. 12.970 is letter-graded.
Woods Hole Staff
12.970: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.971: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.980, 12.981 Current Research in Atmospheric Science
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.980: TBA.
12.981: TBA.
______
Original investigations on problems in atmospheric science. 12.980 is letter-graded.
EAPS Staff
12.980: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.981: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.982, 12.983 Current Research in Climate Physics and Chemistry
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.982: TBA.
12.983: TBA.
______
Original investigations, laboratory work, or fieldwork in problems related to climate. 12.982 is letter-graded
PAOC faculty
12.982: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.983: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.S488, 12.S489 Special Seminar in Structural Geology
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Organized lecture or laboratory subject on an aspect of structural geology not normally covered in regularly scheduled subjects. 12.488 is letter-graded.
Geology and Geochemistry Staff

12.S490, 12.S491 Special Seminar in Geology and Geochemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Organized lecture or laboratory subject on an aspect of geology or geochemistry not normally covered in regularly scheduled subjects. 12.490 is letter-graded.
Geology and Geochemistry Staff

12.S492, 12.S493 Special Seminar in Geobiology
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Organized lecture or laboratory subject on an aspect of geobiology not normally covered in regularly scheduled subjects. 12.492 is letter-graded.
Geobiology Staff

12.S590, 12.S591 Special Seminar in Geophysics
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Organized lecture or laboratory subject on an aspect of geophysics not normally covered in regularly scheduled subjects. 12.S590 is letter-graded.
Consult EAPS Education Office

12.S592, 12.S593 Special Seminar in Earth, Atmospheric and Planetary Sciences
______

Not offered academic year 2016-2017Graduate (IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.S593: URL: http://eapsweb.mit.edu/academics/courses/seminars
______
Organized lecture or laboratory subject on an aspect of the earth sciences, planetary sciences, or astronomy not normally covered in regularly scheduled subjects. 12.592 is letter-graded.
EAPS Staff

12.S680, 12.S681 Special Seminar in Planetary Science
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
12.S680: URL: http://eapsweb.mit.edu/academics/courses/seminars
12.S680: Friday class meets in 54-824. Lecture: TF10-11.30 (54-1623)
______
Organized lecture or laboratory subject on an aspect of planetary science not normally covered in regularly scheduled subjects. 12.S680 is letter-graded.
Planetary Science Staff
12.S680: No textbook information available

12.S990, 12.S991 Special Subject in Atmospheric Science
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
12.S990: URL: http://eapsweb.mit.edu/academics/courses/seminars
______
Organized lecture or laboratory subject on an aspect of atmospheric science not normally covered in regularly scheduled subjects. 12.S990 is letter-graded.
PAOC Staff

12.S992, 12.S993 Special Subject in Climate Physics and Chemistry
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.S993: URL: http://eapsweb.mit.edu/academics/courses/seminars
12.S993: Lecture: F9 (54-915)
______
Organized lecture or laboratory subject on an aspect of climate not normally covered in the regularly scheduled subjects. 12.S992 is letter-graded.
PAOC Staff
12.S993: No textbook information available


left arrow|12.00-12.439 plus UROP, IND, TIP, ThU|12.440-12.599 plus ThG|12.600-12.999|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 14: Economics
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Course 14: Economics
Fall 2016


General Economics and Theory

14.003 Microeconomic Theory and Public Policy
______

Graduate (Fall, Spring)
(Subject meets with14.03)
Prereq: 14.01 or permission of instructor
Units: 4-0-8
Lecture: MW9.30-11 (E52-164) Recitation: F9 (4-237) or F10 (4-237) +final
______
Applies microeconomic theory to analysis of public policy. Builds from microeconomic model of consumer behavior; extends to operation of single and multiple markets and analysis of why markets sometimes fail. Empirical examples to evaluate theory, focusing on the casual effects of policy interventions on economic outcomes. Topics include minimum wages and employment, food stamps and consumer welfare, economics of risk and safety regulation, the value of education, and gains from international trade. Graduate students are expected to complete additional assignments.
Fall:D. Autor
Spring:S. Kerr
Textbooks (Fall 2016)

14.01 Principles of Microeconomics
______

Undergrad (Fall, Spring) HASS Social Sciences
Prereq: None
Units: 3-0-9
Lecture: MW3 (E25-111) Recitation: F10 (5-134) or F11 (5-217) or F12 (5-217) or F1 (1-135) or F3 (4-270) or MWF11 (1-190) or MWF1 (35-308) +final
______
Introduces microeconomic concepts and analysis, supply and demand analysis, theories of the firm and individual behavior, competition and monopoly, and welfare economics. Applications to problems of current economic policy. Taught in two formats - lecture/recitation and recitation only - each with 3 sessions per week. Same content and exams.
Fall:C. Rothschild
Spring:J. Harris
Textbooks (Fall 2016)

14.02 Principles of Macroeconomics
______

Undergrad (Fall, Spring) HASS Social Sciences
Prereq: None
Units: 3-0-9
Lecture: MW2 (10-250) Recitation: F12 (1-190) or F1 (1-190) or MWF10 (35-308) or MWF11 (35-308)
______
Provides an overview of macroeconomic issues: the determination of output, employment, unemployment, interest rates, and inflation. Monetary and fiscal policies are discussed. Important current policy debates such as the sub-prime crisis, social security, the public debt, and international economic issues are critically explored. Introduces basic models of macroeconomics and illustrates principles with the experience of the US and foreign economies. Taught in two formats - lecture/recitation and recitation only - each with 3 sessions per week. Same content and exams.
Fall:R. Caballero
Spring:J. Poterba
Textbooks (Fall 2016)

14.03 Microeconomic Theory and Public Policy
______

Undergrad (Fall, Spring) HASS Social Sciences
(Subject meets with14.003)
Prereq: 14.01
Units: 4-0-8
Lecture: MW9.30-11 (E52-164) Recitation: F9 (4-237) or F10 (4-237) +final
______
Applies microeconomic theory to analysis of public policy. Builds from microeconomic model of consumer behavior; extends to operation of single and multiple markets and analysis of why markets sometimes fail. Empirical examples to evaluate theory, focusing on the casual effects of policy interventions on economic outcomes. Topics include minimum wages and employment, food stamps and consumer welfare, economics of risk and safety regulation, the value of education, and gains from international trade.
Fall:D. Autor
Spring:S. Kerr
Textbooks (Fall 2016)

14.04 Intermediate Microeconomic Theory
______

Undergrad (Spring) HASS Social Sciences
Prereq: 14.01, Calculus II (GIR)
Units: 4-0-8
______
Analysis of consumer and producer decisions including analysis of competitive and monopolistic markets. Price-based partial and general equilibrium analysis. Introduction to game theory as a foundation for the strategic analysis of economic situations. Imperfect competition, dynamic games among firms. Failures of general equilibrium theory and their resolutions: externalities, public goods, incomplete information settings, signaling, screening, insurance, alternative market mechanisms, auctions, design of markets.
J. Toikka

14.05 Intermediate Macroeconomics
______

Undergrad (Spring) HASS Social Sciences
Prereq: 14.01, 14.02
Units: 4-0-8
______
Uses the tools of macroeconomics to investigate various macroeconomic issues in depth. Topics range from economic growth and inequality in the long run to economic stability and financial crises in the short run. Surveys many economic models used today. Requires a substantial research paper on the economics of long-run economic growth.
A. Simsek

14.06 Advanced Macroeconomics
______

Undergrad (Fall) HASS Social Sciences
Prereq: 14.01, 14.02
Units: 4-0-8
Lecture: TR10.30-12 (E51-151) Recitation: F10 (E51-151) +final
______
Blends a thorough study of the theoretical foundations of modern macroeconomics with a review of useful mathematical tools, such as dynamic programming, optimal control, and dynamic systems. Develops comfort with formal macroeconomic reasoning and deepens understanding of key macroeconomic phenomena, such as business cycles. Goes on to study more specific topics, such as unemployment, financial crises, and the role of fiscal and monetary policy. Special attention to reviewing relevant facts and disentangling them from their popular interpretations. Uses insights and tools from game theory. Includes applications to recent and historical events.
G. M. Angeletos
Textbooks (Fall 2016)

14.08 Technical Topics in Economics
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: 14.01
Units: 4-0-8
TBA.
______
Considers technical issues of current research interest in economics.
Consult Department Headquarters
No required or recommended textbooks

14.09 Reading Seminar in Economics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 14.04, 14.06
Units arranged [P/D/F]
TBA.
______
Reading and discussion of particular topics in economics. Open to undergraduate students by arrangement with individual faculty members. Consult Department Headquarters.
A. Mikusheva
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

14.10 Reading Seminar in Economics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 14.04, 14.06
Units arranged
TBA.
______
Reading and discussion of particular topics in economics. Open to undergraduate students by arrangement with individual faculty members. Consult Department Headquarters.
A. Mikusheva
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

14.11 Topics in Economics
______

Undergrad (Fall) HASS Social Sciences Can be repeated for credit
Prereq: 14.01
Units: 4-0-8
Lecture: TR2.30-4 (1-190) Recitation: F10 (1-190)
______
Considers issues of current research interest in economics.
S. Heller
No required or recommended textbooks

14.12 Economic Applications of Game Theory
______

Undergrad (Fall) HASS Social Sciences
Prereq: 14.01; 6.041B or permission of instructor
Units: 4-0-8
Lecture: TR2.30-4 (E52-164) Recitation: F10 (E52-164) or F2 (E51-395) or F3 (E51-395) +final
______
Analysis of strategic behavior in multi-person economic settings. Introduction to solution concepts, such as rationalizability, backwards induction, Nash equilibrium, subgame-perfect equilibrium, and sequential equilibrium, with a strong emphasis on the assumptions behind these solution concepts. Issues of incomplete information, such as signaling and reputation formation. Applications drawn from microeconomics and political economy.
M. Yildiz
Textbooks (Fall 2016)

14.121 Microeconomic Theory I
______

Graduate (Fall); first half of term
Prereq: 14.04, permission of instructor
Units: 3-0-3
Ends Oct 21. Lecture: MW1-2.30 (E51-395) Recitation: F1-2.30 (E51-057)
______
Covers consumer and producer theory, uncertainty, and markets and competition. Studies the tools of comparative statics and their application to price theory. Enrollment limited; preference to PhD students.
A. Wolitzky
Textbooks (Fall 2016)

14.122 Microeconomic Theory II
______

Graduate (Fall); second half of term
Prereq: 14.121, permission of instructor
Units: 3-0-3
Begins Oct 24. Lecture: MW1-2.30 (E51-395) Recitation: F1-2.30 (E51-057) +final
______
Introduction to game theory. Topics include normal form and extensive form games, and games with incomplete information. Enrollment limited.
G. Ellison
Textbooks (Fall 2016)

14.123 Microeconomic Theory III
______

Graduate (Spring)
Prereq: 14.121, 14.122, permission of instructor
Units: 3-0-3
______
General equilibrium theory, a framework linking together micro and macroeconomics, and economic science. Covers Walrasian equilibrium (existence and computation, first and second welfare theorems); general implementation (the core, Nash bargaining, strategic market games); the representative consumer and Gorman aggregation; measurement and the organization of data; and calibration and econometric identification. Applications include uncertainty (risk sharing and financial markets); contracts and information economics; village economies and national development; models with money and credit; trade, spatial economics and differentiated commodities. Enrollment limited.
D. Fudenberg

14.124 Microeconomic Theory IV
______

Graduate (Spring)
Prereq: 14.123, permission of instructor
Units: 3-0-3
______
Decision-making under uncertainty, information economics, incentive and contract theory. Enrollment limited.
B. Holmstrom

14.125 Market Design
______

Graduate (Spring)
Prereq: 14.124
Units: 4-0-8
______
Theory and practice of market design, building on ideas from microeconomics, game theory and mechanism design. Prominent case studies include auctions, labor markets, school choice, prediction markets, financial markets, and organ exchange clearinghouses.
P. Pathak

14.126 Game Theory
______

Graduate (Spring)
Prereq: 14.122
Units: 3-0-9
______
Rigorous investigation of the evolutionary and epistemic foundations of solution concepts, such as rationalizability and Nash equilibrium. Covers classical topics, such as repeated games, bargaining, and supermodular games as well as new topics such as global games, heterogeneous priors, psychological games, and games without expected utility maximization. Applications provided when available.
D. Fudenberg, M. Yildiz

14.129 Advanced Contract Theory
______

Graduate (Spring); second half of term
Prereq: 14.121, 14.281, or permission of instructor
Units: 3-0-3
______
Recent developments in contract theory. Includes advanced models of moral hazard, adverse selection, mechanism design and incomplete contracts with applications to theory of the firm, organizational design, and financial structure.
Consult R. Townsend

14.13 Economics and Psychology
______

Undergrad (Fall) HASS Social Sciences ( HASS Elective )
Prereq: 14.01
Units: 4-0-8
Lecture: TR9-10.30 (E51-151) Recitation: F9 (E51-151) +final
______
Introduces the theoretical and empirical literature of behavioral economics. Examines important and systematic departures from the standard model in economics; covers intertemporal tradeoffs, risk preferences, social preferences, and intrinsic motivation; and applies theory to many different areas, such as credit card debt, addiction, portfolio choices, labor supply, and compensation policies of firms. Students review evidence from lab experiments, examine how the results can be integrated into models, and test models using field and lab data.
F. Schilbach
No textbook information available

14.137[J] Psychology and Economics
______

Graduate (Spring)
(Same subject as9.822[J])
Prereq: None
Units: 4-0-8
______
Examines "psychology appreciation" for economics students. Aims to enhance knowledge and intuition about psychological processes in areas relevant to economics. Increases understanding of psychology as an experimental discipline, with its own distinct rules and style of argument. Topics include self-knowledge, cognitive dissonance, self-deception, emotions, social norms, self-control, learning, mental accounting, memory, individual and group behavior, and some personality and psycho-analytic models. Within each of these topics, we showcase effective and central experiments and discuss their role in the development of psychological theory. Term paper required.
D. Prelec

14.147 Topics in Game Theory
______

Graduate (Spring)
Prereq: 14.126
Units: 4-0-8
______
Advanced subject on topics of current research interest.
J. Toikka, M. Yildiz

14.15[J] Networks
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Social Sciences
(Same subject as6.207[J])
Prereq: 6.041B or 14.30
Units: 4-0-8
______
Highlights common principles that permeate the functioning of diverse technological, economic and social networks. Utilizes three sets of tools for analyzing networks--random graph models, optimization, and game theory--to study informational and learning cascades; economic and financial networks; social influence networks; formation of social groups; communication networks and the Internet; consensus and gossiping; spread and control of epidemics; control and use of energy networks; and biological networks.
Consult Department Headquarters

14.16 Strategy and Information
______

Undergrad (Spring) HASS Social Sciences
Prereq: 14.12 or permission of instructor
Units: 4-0-8
______
Begins with a rigorous overview of the main equilbrium concepts for non-cooperative games in normal and extensive form, with complete or incomplete information. Defines and explores properties of iterated dominance, rationalizability, Nash equilibrium, subgame perfection, perfect Bayesian equilibrium, and sequential, perfect and proper equilibria. Introduces solution concepts for cooperative games and studies non-cooperative implementations. Other topics include matching and allocation problems, auctions and mechanism design, and reputation. Bargaining and networks are recurring themes.
M. Manea

14.160 Behavioral Economics
______

Graduate (Fall)
Prereq: 14.122
Units: 4-0-8
Lecture: TR EVE (4.30-6 PM) (E51-390) Recitation: F4 (E51-361)
______
Covers recent theory and empirical evidence in behavioral economics. Topics include deviations from the neoclassical model in terms of (i) preferences (present bias, reference dependence, social preferences), (ii) beliefs (overconfidence, projection bias), and (iii) decision-making (cognition, attention, framing, persuasion), as well as (iv) market reactions to such deviations. Applications will cover a large range of fields, including labor and public economics, industrial organization, health economics, finance, and development economics.
A. Banerjee, F. Schilbach
No textbook information available

14.18 Mathematical Economic Modeling
(New)
______

Undergrad (Fall) HASS Social Sciences
Prereq: 14.04, 14.12, 14.15, or 14.19
Units: 4-0-8
Lecture: TR10.30-12 (E51-372) Recitation: F10 (E51-372)
______
Guides students through the process of developing and analyzing formal economic models and effectively communicating their results. Topics include decision theory, game theory, voting, and matching. Instruction and practice in oral and written communication provided. Prior coursework in microeconomic theory and/or proof-based mathematics required.
A. Wolitzky
No textbook information available

14.19 Market Design
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Social Sciences
Prereq: 14.01
Units: 4-0-8
______
Covers the design and operation of organized markets, building on ideas from microeconomic and game theory. Topics may include mechanism design, auctions, matching markets, and other resource allocation problems.
Consult P. Pathak

14.191 Independent Research Paper
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units: 0-12-0
TBA.
______
Under supervision of a faculty member approved by Graduate Registration Officer, student writes a substantial, probably publishable research paper. Must be completed by the end of a student's second year to satisfy the departmental minor requirement.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

14.193 Advanced Seminar in Economics
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: 14.121, 14.451
Units arranged
14.193: Lecture: M12.30-2.30 (E52-314)
______
Reading and discussion of current topics in economics. Open to advanced graduate students by arrangement with individual members of the staff.
D. Fudenberg
14.193: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

14.195 Reading Seminar in Economics
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: 14.121
Units arranged [P/D/F]
14.195: TBA.
______
Reading and discussion of current topics in economics. Open to advanced graduate students by arrangement with individual members of the staff.
Staff
14.195: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

14.197 Independent Research
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Under supervision of a faculty member approved by Graduate Registration Officer, student conducts independent research.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

14.198, 14.199 Teaching Introductory Economics
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units: 2-0-2 [P/D/F]
14.198: TBA.
14.199: TBA.
______
Required of teaching assistants in introductory economics (14.01 and 14.02), under supervision of the faculty member in charge of the subject.
14.198:J. Gruber, J. Harris
14.199:R. Caballero, J. Poterba
14.198: No required or recommended textbooks
14.199: No required or recommended textbooks

Industrial Organization

14.20 Industrial Organization and Competitive Strategy
______

Undergrad (Spring) HASS Social Sciences
Prereq: 14.01
Units: 4-0-8
______
Analyzes the behavior and performance of firms in markets, with a particular focus on strategic interactions. Topics include monopoly power, behavior of firms in oligopoly markets, static and dynamic measurement of market performance, pricing and product choice decisions, advertising, research and development, and theory of the firm. Requires attendance and team participation in a Competitive Strategy Game.
N. Rose

14.21 Health Economics
______

Undergrad (Spring) HASS Social Sciences
Prereq: 14.01
Units: 3-0-9
URL: http://web.mit.edu/14.21j/www/
______
Applies theoretical and empirical tools of economics to problems of health and medical care delivery. Concentrates on selected topics such as decision-making under uncertainty, cost-benefit analysis, health insurance, physician remuneration, government regulation, health care systems of developing countries, and the economics of AIDS.
J. E. Harris

14.26 Economics of Incentives: Theory and Applications
______

Undergrad (Spring) HASS Social Sciences
Prereq: 14.01
Units: 4-0-8
______
Provides a rigorous, but not overly technical introduction to the economic theory of incentives and organization together with a varying set of applications. These include, among others, the optimal design of sales and CEO incentive schemes; the impact of incentives on risk taking and innovation; tournament design; the analysis of venture capital and other forms of financial incentive contracts; relational and behavioral aspects of incentive contracts; and various organizational design problems.
B. Holmstrom

14.27 Economics and E-Commerce
______

Undergrad (Fall) HASS Social Sciences
Prereq: 14.01; 6.041B or 14.30
Units: 4-0-8
URL: http://ocw.mit.edu/courses/economics/14-27-economics-and-e-commerce-fall-2014/
Lecture: MW10.30-12 (E51-372) Recitation: F11 (E51-361)
______
Uses theoretical economic models and empirical evidence to help understand the growth and future of e-commerce. Economic models help frame class discussions of, among other topics, content provision, privacy, piracy, sales taxation, group purchasing, price search, and advertising on the internet. Empirical project and paper required.
S. Ellison
No textbook information available

14.271 Industrial Organization I
______

Graduate (Fall)
Prereq: 14.04
Units: 5-0-7
Lecture: MW9-10.30 (E51-376) Recitation: F9-10.30 (E51-361) +final
______
Covers theoretical and empirical work dealing with the structure, behavior, and performance of firms and markets and core issues in antitrust. Topics include: the organization of the firm, monopoly, price discrimination, oligopoly, and auctions. Theoretical and empirical work are integrated in each area.
G. Ellison
Textbooks (Fall 2016)

14.272 Industrial Organization II
______

Graduate (Spring)
Prereq: 14.271
Units: 5-0-7
______
A continuation of 14.271. Topics covered include horizontal mergers and demand estimation, vertical integration and vertical restraints, natural monopoly and its regulation, public enterprise, political economy of regulation, network access pricing, deregulation of telecommunications, electric power, cable television, transportation sectors, and risk and environmental regulation.
N. Rose, M. Whinston

14.273 Advanced Topics in Industrial Organization
______

Graduate (Spring)
Prereq: 14.271
Units: 5-0-7
______
Empirical analysis of theoretically derived models of market behavior. Varied topics include demand estimation, differentiated products, production functions, analysis of market power, entry and exit, vertical relationships, auctions, matching markets, network externalities, dynamic oligopoly, moral hazard and adverse selection. Discussion will focus on methodological issues, including identification, estimation, counter-factual analysis and simulation techniques.
S. Ellison, W. Newey

14.281 Contract Economics
______

Graduate (Fall)
Prereq: 14.124
Units: 4-0-8
Lecture: MW10.30-12 (E51-361) Recitation: F12 (E51-372)
______
Covers theoretical research on contracts in static as well as dynamic settings. Emphasis is on canonical models in contracting (agency theory, mechanism design, incomplete contracting) illustrated by major areas of application (e.g. compensation, labor and capital markets, property rights, organizational design, corporate finance).
J. Toikka
No textbook information available

14.282 Introduction to Organizational Economics
______

Graduate (Fall)
Prereq: 14.124
Units: 5-0-7
Lecture: TR1-2.30 (E62-550) Recitation: F2.30-4 (E62-550) +final
______
Begins with survey of contract theory for organizational economists, then introduces the main areas of the field, including the boundary of the firm; decision-making, employment, structures and processes in organizations; and organizations other than firms.
R. Gibbons, J. Van Reenen, M. Whinston
No textbook information available

14.283 Advanced Topics in Organizational Economics I
______

Graduate (Spring); first half of term
Prereq: 14.282
Units: 2-0-4
______
Builds on the work done in 14.282 to develop more in-depth analysis of topics in the field.
R. Gibbons

14.284 Advanced Topics in Organizational Economics II
______

Graduate (Spring); second half of term
Prereq: 14.282
Units: 2-0-4
______
Builds on the work done in 14.282 to develop more in-depth analysis of topics in the field.
J. Van Reenen

Statistics and Econometrics

14.30 Introduction to Statistical Methods in Economics
______

Undergrad (Fall) Rest Elec in Sci & Tech
(Subject meets with14.300)
Prereq: Calculus II (GIR)
Units: 4-0-8
Lecture: TR1-2.30 (E51-057) Recitation: F2 (E51-145) +final
______
Self-contained introduction to probability and statistics with some economic applications. Elements of probability theory, sampling theory, statistical estimation, and hypothesis testing. Students taking graduate version complete additional assignments. May not count toward HASS requirement.
M. Manea
No textbook information available

14.300 Introduction to Statistical Methods in Economics
______

Graduate (Fall)
(Subject meets with14.30)
Prereq: Calculus II (GIR)
Units: 4-0-8
Lecture: TR1-2.30 (E51-057) Recitation: F2 (E51-145) +final
______
Self-contained introduction to probability and statistics with some economic applications. Elements of probability theory, sampling theory, statistical estimation, and hypothesis testing. Graduate students are expected to complete additional assignments.
M. Manea
No textbook information available

14.31 Data Analysis for Social Scientists
______

Undergrad (Spring) Institute Lab
(Subject meets with14.310)
Prereq: Calculus I (GIR)
Units: 4-0-8
______
Introduces methods for harnessing data to answer questions of cultural, social, economic, and policy interest. Presents essential notions of probability and statistics. Covers techniques in modern data analysis: regression and econometrics, prediction, design of experiment, randomized control trials (and A/B testing), machine learning, data visualization, analysis of network data, and geographic information systems. Projects include analysis of data with a written description and interpretation of results; may involve gathering of original data or use of existing data sets. Applications drawn from real world examples and frontier research. Instruction in use of the statistical package Stata. Students taking graduate version complete additional assignments.
D. Atkin, E. Duflo

14.310 Data Analysis for Social Scientists
______

Graduate (Spring)
(Subject meets with14.31)
Prereq: None
Units: 4-0-8
______
Introduces methods for harnessing data to answer questions of cultural, social, economic, and policy interest. Presents essential notions of probability and statistics. Covers techniques in modern data analysis: regression and econometrics, prediction, design of experiment, randomized control trials (and A/B testing), machine learning, data visualization, analysis of network data, and geographic information systems. Projects include analysis of data with a written description and interpretation of results; may involve gathering of original data or use of existing data sets. Applications drawn from real world examples and frontier research. Instruction in use of the statistical package Stata. Students taking graduate version complete additional assignments.
D. Atkin, E. Duflo

14.32 Econometrics
______

Undergrad (Fall)
Prereq: 14.30
Units: 4-0-8
Lecture: TR1-2.30 (E51-376) Recitation: F2 (E51-372) +final
______
Introduction to econometric ideas and methods, emphasizing data analysis for empirical causal inference. Topics include randomized trials, regression, instrumental variables, differences-in-differences, and regression discontinuity designs. Emphasizes applications and includes problem sets. May not count toward HASS requirement.
A. Mikusheva
Textbooks (Fall 2016)

14.33 Research and Communication in Economics: Topics, Methods, and Implementation
______

Undergrad (Fall, Spring) Institute Lab
Prereq: 14.01, 14.02, 14.32
Units: 3-4-5
Lecture: MW9-10.30 (E51-372) Lab: TBA
______
Exposes students to the process of conducting independent research in empirical economics and effectively communicating the results of the research. Emphasizes econometric analysis of an assigned economic question and culminates in each student choosing an original topic, performing appropriate analysis, and delivering oral and written project reports.
S. Ellison
No required or recommended textbooks

14.36 Advanced Econometrics
______

Undergrad (Spring)
Prereq: 14.32
Units: 4-0-8
______
Covers a range of topics including duration models, discrete choice models, differentiated product models, count models and other advanced models that are used in a wide variety of applications in applied microeconomics, financial economics, and business economics. Mastery of one or more techniques taught in class demonstrated through the completion of an econometrics paper.
J. Angrist, V. Chernozhukov

14.381 Statistical Method in Economics
______

Graduate (Fall)
Prereq: Calculus II (GIR), permission of instructor
Units: 5-0-7
Lecture: TR2.30-4 (E51-151) Recitation: F4-5.30 (E51-145) +final
______
Introduction to probability and statistics as background for advanced econometrics and introduction to the linear regression model. Covers elements of probability theory; sampling theory; asymptotic approximations; decision-theory approach to statistical estimation focusing on regression, hypothesis testing; and maximum-likelihood methods. Includes simple and multiple regression, estimation and hypothesis testing. Illustrations from economics and application of these concepts to economic problems. Enrollment limited.
I. Andrews, M. Kolesar
Textbooks (Fall 2016)

14.382 Econometrics
______

Graduate (Spring)
Prereq: 14.381 or permission of instructor
Units: 5-0-7
______
Regression analysis, focusing on departures from the standard Gauss-Markov assumptions, and simultaneous equations. Regression topics include heteroskedasticity, serial correlation, and errors in variables, generalized least squares, nonlinear regression, and limited dependent variable models. Covers identification and estimation of linear and nonlinear simultaneous equations models. Economic applications are discussed. Enrollment limited.
V. Chernozhukov

14.384 Time Series Analysis
______

Graduate (Fall)
Prereq: 14.382 or permission of instructor
Units: 5-0-7
Lecture: TR9-10.30 (E51-372) Recitation: W EVE (5.30-7 PM) (E51-361)
______
Studies theory and application of time series methods in econometrics, including spectral analysis, estimation with stationary and non-stationary processes, VARs, factor models, unit roots, cointegration, estimation of DSGE models, and Bayesian methods. Enrollment limited.
A. Mikusheva
Textbooks (Fall 2016)

14.385 Nonlinear Econometric Analysis
______

Graduate (Fall)
Prereq: 14.382 or permission of instructor
Units: 5-0-7
Lecture: MW1-2.30 (E51-057) Recitation: F1-2.30 (E51-361)
______
Studies micro-econometric models, including large sample theory for estimation and hypothesis testing, generalized method of moments, estimation of censored and truncated specifications, quantile regression, structural estimation, nonparametric and semiparametric estimation, panel data, bootstrapping, and simulation methods. Methods illustrated with economic applications. Enrollment limited.
A. Abadie, I. Andrews
Textbooks (Fall 2016)

14.386 New Econometric Methods
______

Graduate (Spring)
Prereq: 14.382
Units: 4-0-8
______
Focuses on recent developments in econometrics, especially structural estimation. Topics include nonseparable models, models of imperfect competition, auction models, duration models, and nonlinear panel data. Results illustrated with economic applications.
M. Kolesar

14.387 Applied Econometrics
______

Graduate (Spring)
Prereq: 14.382
Units: 4-0-8 [P/D/F]
______
Advanced treatment of core econometric ideas and methods. Emphasizes econometric theory and applications. Covers topics such as regression, instrumental variables, differences-in-differences, regression discontinuity designs, and problems related to standard errors and statistical inference. Includes problem sets with a theoretical and data-analytic component.
J. Angrist, V. Chernozhukov

14.389 Econometrics Paper
______

Graduate (IAP)
Prereq: 14.382 or 14.32
Units: 0-0-3
______
Paper in econometrics required of all PhD candidates. Paper due at the end of IAP.
A. Abadie

14.391 Workshop in Economic Research
______

Graduate (Fall) Can be repeated for credit
Prereq: 14.124, 14.454
Units: 2-0-10 [P/D/F]
Recitation: T EVE (4-6 PM) (E51-376) or M2.30-4 (E62-450) or M4-5.30 (E51-151) or R EVE (4-6 PM) (E53-482, E51-151) or M4-5.30 (E52-164) or T2.30-4 (HARVARD, E62-650) or W4-5.30 (E51-151) or R4-5.30 (E52-432)
______
No required or recommended textbooks

14.392 Workshop in Economic Research
______

Graduate (Spring) Can be repeated for credit
Prereq: 14.124, 14.454
Units: 2-0-10 [P/D/F]
______
Develops research ability of students through intensive discussion of dissertation research as it proceeds, individual or group research projects, and critical appraisal of current reported research. Workshops divided into various fields, depending on interest and size.
Staff

For additional related subjects in Statistics, see:

Civil and Environmental Engineering: 1.151, 1.155, 1.202J, 1.203J, 1.205J

Electrical Engineering and Computer Science: 6.041, 6.231, 6.245, 6.262, 6.431, 6.432, and 6.435

Management: 15.034, 15.061, 15.065, 15.070, 15.075, 15.076, 15.098, and 15.306

Mathematics: 18.05, 18.175, 18.177, 18.440, 18.441, 18.443, 18.445, 18.458, and 18.465

See also: 2.061, 2.830, 5.70, 5.72, 7.02, 8.044, 8.08, 10.816, 11.220, 11.221, 16.322, 17.872, 17.874, 22.38, HST.191, and MAS.622J.


left arrow|14.00-14.399 plus UROP|14.40-14.999 and UROP and Thesis|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 14: Economics
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Course 14: Economics
Fall 2016


National Income and Finance

14.41 Public Finance and Public Policy
______

Undergrad (Spring) HASS Social Sciences
(Subject meets with14.410)
Prereq: 14.01
Units: 4-0-8
Subject Cancelled Subject Cancelled
______
Explores the role of government in the economy, applying tools of basic microeconomics to answer important policy questions such as government response to global warming, school choice by K-12 students, Social Security versus private retirement savings accounts, government versus private health insurance, setting income tax rates for individuals and corporations. Students taking the graduate version complete additional assignments.
R. McKnight

14.410 Public Finance and Public Policy
(New)
______

Graduate (Spring)
(Subject meets with14.41)
Prereq: 14.01
Units: 4-0-8
Subject Cancelled Subject Cancelled
______
Explores the role of government in the economy, applying tools of basic microeconomics to answer important policy questions such as government response to global warming, school choice by K-12 students, Social Security versus private retirement savings accounts, government versus private health insurance, setting income tax rates for individuals and corporations. Students taking the graduate version complete additional assignments.
R. McKnight

14.416[J] Introduction to Financial Economics
______

Graduate (Fall)
(Same subject as15.416[J])
Prereq: 14.121, 14.122
Units: 4-0-8
Lecture: MW2.30-4 (E51-063) Recitation: F11 (E62-221)
______
Foundations of modern financial economics; individuals' consumption and portfolio decisions under uncertainty; valuation of financial securities. Topics include expected utility theory; stochastic dominance; mutual fund separation; portfolio frontiers; capital asset pricing model; arbitrage pricing theory; Arrow-Debreu economies; consumption and portfolio decisions; consumption beta models; spanning; options; market imperfections; no-trade theorems; rational expectations; financial signaling. Primarily for doctoral students in accounting, economics, and finance.
S. Ross
Textbooks (Fall 2016)

14.42 Environmental Policy and Economics
______

Undergrad (Spring) HASS Social Sciences
Prereq: 14.01
Units: 4-0-8
______
Investigates the proper role of government in the regulation of the environment. Presents tools necessary to estimate the costs and benefits of a variety of environmental policies. Focuses on both conceptual thinking and quantitative evaluation of environmental issues. Gives particular attention to climate change: defines the major concepts underlying the climate problem; examines the measurement of climate damages as well as the costs of mitigating them; and discusses the various policy options available to communities, countries, and international coalitions. Completion of 14.30 or equivalent statistics subject strongly recommended.
S. Stolper

14.43[J] Energy Decisions, Markets, and Policies
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject as11.161[J],15.031[J],17.397[J],21A.415[J])
Prereq: 14.01, 15.0111, or permission of instructor
Units: 4-0-8
______
Structured around choices and constraints regarding sources and uses of energy by households, firms, and governments, introduces managerial, economic, political, social and cultural frameworks for describing and explaining behavior at various levels of aggregation. Includes examples of cost-benefit, organizational and institutional analyses of energy generation, distribution, and consumption. Topics include the role of markets and prices; financial analysis of energy-related investments; institutional path dependence; economic and political determinants of government regulation and the impact of regulation on decisions; and other forms of government action and social norms regarding desired behavior and opportunities for businesses and consumers, including feedback into the political/regulatory system. Examples drawn from a wide range of countries and settings.
C. Warshaw

14.44[J] Energy Economics and Policy
______

Undergrad (Spring) HASS Social Sciences
(Same subject as15.037[J])
Prereq: 14.01
Units: 4-0-8
Credit cannot also be received for14.444,15.038
______
Analyzes business and public policy issues in energy markets and in the environmental markets to which they are closely tied. Examines the economic determinants of industry structure and evolution of competition among firms in these industries. Investigates successful and unsuccessful strategies for entering new markets and competing in existing markets. Industries studied include oil, natural gas, coal, electricity, and transportation. Topics include climate change and environmental policy, the role of speculation in energy markets, the political economy of energy policies, and market power and antitrust. Two team-based simulation games, representing the world oil market and a deregulated electricity market, act to cement the concepts covered in lecture. Students taking graduate version complete additional assignments. Limited to 60.
C. Knittel

14.440[J] Advanced Financial Economics I
______

Graduate (Spring)
(Same subject as15.440[J])
Prereq: 15.416
Units: 5-0-7
______
Covers advanced topics in the theory of financial markets with a focus on continuous time models. Topics include multiperiod securities markets and martingales; pricing of contingent securities such as options; optimal consumption and portfolio problems of an individual; dynamic equilibrium theory and the intertemporal capital asset pricing model; term structure of interest rates; and equilibrium with asymmetric information, transaction costs, and borrowing constraints. Primarily for doctoral students in finance, economics, and accounting.
H. Chen, L. Kogan

14.441[J] Advanced Financial Economics II
______

Graduate (Spring)
(Same subject as15.441[J])
Prereq: 14.121, 14.122, or 15.416J
Units: 3-0-9
______
Surveys selected topics in current advanced research in corporate finance. Theoretical and empirical analyses of corporate financing and investment decisions. Some background in information economics and game theory is useful. Primarily for doctoral students in accounting, economics, and finance.
Staff

14.442[J] Advanced Financial Economics III
______

Graduate (Fall)
(Same subject as15.442[J])
Prereq: 14.382, 15.416J, or permission of instructor
Units: 3-0-9
Lecture: TR2.30-4 (E62-687) Recitation: M EVE (6-7.30 PM) (E51-372)
______
Recent empirical methods in finance, including: the estimation and testing of market efficiency; the random walk hypothesis; the CAPM/APT; various term structure models; option pricing theories; and market microstructures; performance evaluation; bond rating and default analysis; event study methodology; continuous-time econometrics; and general time series methods. An empirical term project is required. Some econometric background and rudimentary computer programming skills are assumed. Primarily for doctoral students in finance, accounting, and economics.
Staff
Textbooks (Fall 2016)

14.444[J] Energy Economics and Policy
______

Graduate (Spring)
(Same subject as15.038[J])
Prereq: 14.01
Units: 4-0-8
Credit cannot also be received for14.44,15.037
______
Theoretical and empirical perspectives on individual and industrial demand for energy, energy supply, energy markets, and public policies affecting energy markets. Discusses aspects of the oil, natural gas, electricity, and nuclear power sectors. Examines energy tax, price regulation, deregulation, energy efficiency and policies for controlling pollution and CO2 emissions. Students taking the graduate version complete additional assignments. Limited to 60.
C. Knittel

14.451 Dynamic Optimization Methods with Applications
______

Graduate (Fall); first half of term
Prereq: 14.06, permission of instructor
Units: 3-0-3
Ends Oct 21. Lecture: TR1-2.30 (E51-151) Recitation: F2.30-4 (E51-151)
______
Provides an introduction to dynamic optimization methods, including discrete-time dynamic programming in non-stochastic and stochastic environments, and continuous time methods including the Pontryagin maximum principle. Applications may include the Ramsey model, irreversible investment models, and consumption choices under uncertainty. Enrollment limited.
A. Simsek
Textbooks (Fall 2016)

14.452 Economic Growth
______

Graduate (Fall); second half of term
Prereq: 14.451, permission of instructor
Units: 3-0-3
Begins Oct 24. Lecture: TR1-2.30 (E51-151) Recitation: F2.30-4 (E51-151) +final
______
Introduces the sources and modeling of economic growth and income differences across nations. Topics include an introduction to dynamic general equilibrium theory, the neoclassical growth model, overlapping generations, determinants of technological progress, endogenous growth models, measurement of technological progress, the role of human capital in economic growth, and growth in a global economy. Enrollment limited.
D. Acemoglu
No textbook information available

14.453 Economic Fluctuations
______

Graduate (Spring); first half of term
Prereq: 14.452, permission of instructor
Units: 3-0-3
______
Investigation of why aggregate economic activity fluctuates, and the role of policy in affecting fluctuations. Topics include the link between monetary policy and output, the economic cost of aggregate fluctuations, the costs and benefits of price stability, and the role of central banks. Introduction to real business cycle and new Keynesian models. Enrollment limited.
G. M. Angeletos

14.454 Economic Crises
______

Graduate (Spring); second half of term
Prereq: 14.453, permission of instructor
Units: 3-0-3
______
Introduction to current macroeconomic concerns with particular emphasis on medium-run economic fluctuations, economic crises, and the role of asset markets. Topics include the explanation of high chronic unemployment in some nations, the source of modern liquidity crises, the origin and end of speculative bubbles, and the factors that lead to substantial periods of economic stagnation. Enrollment limited.
R. Caballero

14.461 Advanced Macroeconomics I
______

Graduate (Fall)
Prereq: 14.122, 14.452
Units: 5-0-7
Lecture: TR1-2.30 (E51-361) Recitation: F2.30-4 (E51-361)
______
Advanced subject in macroeconomics that seeks to bring students to the research frontier. Topics vary from year to year, covering a wide spectrum of classical and recent research. Topics may include business cycles, optimal monetary and tax policy, monetary economics, banking, and financial constraints on investment and incomplete markets.
D. Acemolgu, I. Werning
No textbook information available

14.462 Advanced Macroeconomics II
______

Graduate (Spring)
Prereq: 14.461
Units: 5-0-7
______
Advanced topics on business cycles and crises; informational frictions; coordination problems; global games; DSGE models; financial frictions.
E. Nakamura, R. Townsend

14.471 Public Economics I
______

Graduate (Fall)
Prereq: 14.04
Units: 4-0-8
Lecture: MW2.30-4 (E51-361) Recitation: F12 (E51-361)
______
Theory and evidence on government taxation policy. Topics include tax incidence; optimal tax theory; the effect of taxation on labor supply and savings; taxation and corporate behavior; and tax expenditure policy.
J. Poterba, I. Werning
No required or recommended textbooks

14.472 Public Economics II
______

Graduate (Spring)
Prereq: 14.471
Units: 3-0-9
______
Theory and evidence on government expenditure policy and on regulatory and tax responses to problems of market failure. Focuses on social insurance programs such as social security and unemployment insurance, and on the causes and consequences of rising health expenditures.
A. Finkelsein

14.473 Public Policy in Health Economics
______

Graduate (Spring)
Prereq: 14.122
Units: 4-0-8
______
Theory and evidence on the economics of the health care sector. Particular focus on the causes and consequences of rising health expenditures; technological change and productivity in the health care sector; and the impact of health insurance.
Consult H. Williams

International, Interregional, and Urban Economics

14.54 International Trade
______

Undergrad (Fall) HASS Social Sciences
Prereq: 14.01, 14.02
Units: 4-0-8
Lecture: MW10.30-12 (E51-057) Recitation: F11 (E52-164) +final
______
Introduction to the theory of international trade and finance with applications to current policy issues.
A. Costinot
Textbooks (Fall 2016)

14.581 International Economics I
______

Graduate (Fall)
Prereq: 14.04
Units: 5-0-7
Lecture: MW9-10.30 (E51-057) Recitation: W12 (E51-057)
______
Theory of international trade and foreign investment with applications in commercial policy.
D. Atkin, A. Costinot
Textbooks (Fall 2016)

14.582 International Economics II
______

Graduate (Spring)
Prereq: 14.06
Units: 5-0-7
______
Covers international capital flows, exchange rate fluctuations, global capital markets, emerging markets, crises, sovereign debt, international financial architecture, and bubbles.
A. Costinot

Labor Economics and Industrial Relations

14.64 Labor Economics and Public Policy
______

Not offered academic year 2017-2018Undergrad (Spring) HASS Social Sciences
Prereq: 14.30 or permission of instructor
Units: 4-0-8
______
Provides an introduction to the labor market, how it functions, and the important role it plays in people's lives world-wide. Topics include supply and demand, minimum wages, labor market effects of social insurance and welfare programs, the collective bargaining relationship, discrimination, human capital, and unemployment. Completion of or concurrent enrollment in 14.03 or 14.04 recommended.
J. Angrist

14.661 Labor Economics I
______

Graduate (Fall)
Prereq: 14.04, 14.32
Units: 5-0-7
Lecture: TR10.30-12 (E51-145) Recitation: F10.30-12 (E51-061) +final
______
A systematic development of the theory of labor supply, labor demand, and human capital. Topics include wage and employment determination, turnover, search, immigration, unemployment, equalizing differences, and institutions in the labor market. Particular emphasis on the interaction between theoretical and empirical modeling.
D. Acemoglu, J. Angrist
Textbooks (Fall 2016)

14.662 Labor Economics II
______

Graduate (Spring)
Prereq: 14.04, 14.32
Units: 5-0-7
______
Theory and evidence on the determinants of earnings levels, inequality, intergenerational mobility, skill demands, and employment structure. Particular focus on the determinants of worker- and firm-level productivity; and the roles played by supply, demand, institutions, technology and trade in the evolving distribution of income.
D. Autor, H. Williams

Economic History

14.70[J] Medieval Economic History in Comparative Perspective
______

Undergrad (Spring) HASS Social Sciences Communication Intensive HASS
(Same subject as21H.134[J])
Prereq: None
Units: 3-0-9
______
Surveys the conditions of material life and changing social and economic relations in medieval Europe using the comparative context of contemporary Islamic, Chinese, and Japanese experiences. Covers the emergence and decline of feudal institutions, the transformation of peasant agriculture, living standards and the course of epidemic disease, and the ebb and flow of long-distance trade across the Eurasian system. Particular emphasis placed on the study of those factors, both institutional and technological, which contributed to the emergence of capitalist organization and economic growth in western Europe in contrast to the trajectories followed by the other major medieval economies.
A. McCants

14.73 The Challenge of World Poverty
______

Undergrad (Fall) HASS Social Sciences Communication Intensive HASS
Prereq: None
Units: 4-0-8
Lecture: MW1-2.30 (E51-151) Recitation: F1 (E25-117, E51-085) or F2 (E25-117) +final
______
Designed for students who are interested in the challenge posed by massive and persistent world poverty. Examines extreme poverty over time to see if it is no longer a threat, why some countries grow fast and others fall further behind, if growth or foreign aid help the poor, what we can do about corruption, if markets or NGOs should be left to deal with poverty, where to intervene, and how to deal with the disease burden and improve schools.
E. Duflo, F. Schilbach
Textbooks (Fall 2016)

Economic Development

14.74 Foundations of Development Policy
______

Undergrad (Spring) HASS Social Sciences
(Subject meets with14.740)
Prereq: 14.01, 14.30
Units: 4-0-8
______

14.740 Foundations of Development Policy
______

Graduate (Spring)
(Subject meets with14.74)
Prereq: 14.01, 14.30
Units: 4-0-8
______
Explores the foundations of policy making in developing countries. Goal is to spell out various policy options and to quantify the trade-offs between them. Special emphasis on education, health, gender, fertility, adoption of technological innovation, and the markets for land, credit, and labor. Students taking the graduate version complete additional assignments.
D. Atkin, E. Duflo

14.75 Political Economy and Economic Development
______

Undergrad (Fall) HASS Social Sciences
Prereq: 14.01, 14.30
Units: 4-0-8
Lecture: MW2.30-4 (E51-372) Recitation: F3 (E51-372) +final
______
Explores the relationship between political institutions and economic development, covering key theoretical issues as well as recent empirical evidence. Topics include corruption, democracy, dictatorship, and war. Discusses not just what we know on these topics, but how we know it, covering how to craft a good empirical study or field experiment and how to discriminate between reliable and unreliable evidence.
B. Olken
Textbooks (Fall 2016)

14.770 Introduction to Collective Choice and Political Economy
______

Graduate (Fall)
Prereq: None
Units: 4-0-8
Lecture: TR10.30-12 (E52-532) Recitation: F12
______
Broad introduction to political economy. Covers topics from social choice theory to political agency models, including theories of voter turnout and comparison of political institutions.
A. Banerjee, C. Garcia-Jimeno
No textbook information available

14.771 Development Economics: Microeconomic Issues
______

Graduate (Fall)
Prereq: 14.121, 14.122
Units: 5-0-7
Lecture: MW10.30-12 (E52-432) Recitation: R4 (E51-393) +final
______
A rigorous introduction to core micro-economic issues in economic development, focusing on both key theoretical contributions and empirical applications to understand both why some countries are poor and on how markets function differently in poor economies. Topics include human capital (education and health); labor markets; credit markets; land markets; firms; and the role of the public sector.
E. Duflo, B. Olken
No textbook information available

14.772 Development Economics: Macroeconomics
______

Graduate (Spring)
Prereq: 14.121, 14.451
Units: 5-0-7
______
Dynamic models of growth and development emphasizing migration, modernization, and technological change; static and dynamic models of political economy; the dynamics of income distribution and institutional change; firm structure in developing countries; development, transparency, and functioning of financial markets; privatization; and banks and credit market institutions in emerging markets.
A. Banerjee, R. Townsend

14.773 Political Economy: Institutions and Development
______

Graduate (Spring)
Prereq: 14.121,14.451
Units: 5-0-7
______
Economists and policymakers increasingly realize the importance of political institutions in shaping economic performance, especially in the context of understanding economic development. Work on the determinants of economic policies and institutions is in its infancy, but is growing rapidly. Subject provides an introduction to this area. Topics covered: the economic role of institutions; the effects of social conflict and class conflict on economic development; political economic determinants of macro policies; political development; theories of income distribution and distributional conflict; the efficiency effects of distributional conflict; the causes and consequences of corruption; the role of colonial history; and others. Both theoretical and empirical approaches discussed. Subject can be taken either as part of the Development Economics or the Positive Political Economy fields.
D. Acemoglu, C. Garcia-Jimeno

14.781[J] Political Economy I: Theories of the State and the Economy
______

Graduate (Spring)
(Same subject as15.678[J],17.100[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Critical analysis of liberal, neoclassical, and Marxist perspectives on modern society. Alternative theories of economic growth, historical change, the state, classes, and ideology.
M. Piore, S. Berger

14.999 Topics in Inequality
______

Graduate (Spring)
Prereq: 14.452
Units: 2-0-4
______
Addresses empirical and theoretical issues of inequality from various perspectives, such as macroeconomic, labor, public finance, and political economy.
Consult D. Autor

14.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research and writing of thesis; to be arranged by the student with supervising committee.
Staff
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

14.THU Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 14.33
Units arranged
TBA.
______
Program of research and writing of thesis.
Staff
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

14.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 14.02
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

14.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 14.02
Units arranged
TBA.
______
Participation in research with an individual faculty member or research group, independent research or study under the guidance of a faculty member. Admission by arrangement with individual faculty member.
Consult A. Mikusheva
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|14.00-14.399 plus UROP|14.40-14.999 and UROP and Thesis|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 15: Management
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Course 15: Management
Fall 2016


Managerial Economics

15.002 Sloan Innovation Period Requirement
______

Graduate (Fall, IAP, Spring, Summer)
Prereq: None
Units arranged [P/D/F]
TBA.
______
Units assigned to MBA students upon completion of the Sloan Innovation Period requirement. MBAs only.
Consult D. Gormley
No textbook information available

15.003 Analytics Tools
(New)
______

Graduate (Fall, IAP, Spring, Summer)
Prereq: None
Units: 2-0-1 [P/D/F]
TBA.
______
Units assigned to Master of Business Analytics students upon completion of the Analytics Tools requirement. Restricted to Master of Business Analytics students.
Consult D. Gormley
No textbook information available

15.010 Economic Analysis for Business Decisions
______

Graduate (Fall)
Prereq: None
Units: 4-0-5
Lecture: TR10-11.30 (E62-262, E51-315, E51-325) or TR8.30-10 (E62-262, E51-315, E51-325) Recitation: F12 (E51-345) or F1 (E62-250) or F12 (E51-395) or F1 (E51-395, E51-345) or F12 (E51-325) or F1 (E51-325) or F12 (E51-315) or F1 (E51-315) or F12 (E51-145) or F1 (E51-145) or F12 (E62-250) +final
______
Textbooks (Fall 2016)

15.011 Economic Analysis for Business Decisions
______

Graduate (Fall)
(Subject meets with15.0111)
Prereq: None
Units: 4-0-5
Lecture: TR1-2.30 (E51-335) Recitation: F12 (E51-151) or F1 (E51-151) +final
______
Introduces principles of microeconomics as a framework for making more informed managerial decisions and policy analysis. Includes the analysis of competitive markets with supply and demand, sources of market power and strategic pricing. Also provides an introduction to game theory to illustrate competition, anti-trust policy, and how to generate cooperation both within and between firms. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details. Intended for non-MBA students.
J. Doyle
Textbooks (Fall 2016)

15.0111 Economic Analysis for Business Decisions
______

Undergrad (Fall)
(Subject meets with15.011)
Prereq: None
Units: 4-0-5
Lecture: TR1-2.30 (E51-335) Recitation: F12 (E51-151) or F1 (E51-151) +final
______
Introduces principles of microeconomics as a framework for making more informed managerial decisions and policy analysis. Includes the analysis of competitive markets with supply and demand, sources of market power and strategic pricing. Also provides an introduction to game theory to illustrate competition, anti-trust policy, and how to generate cooperation both within and between firms. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. Doyle
Textbooks (Fall 2016)

15.012 Applied Macro- and International Economics
______

Graduate (Spring); first half of term
Prereq: None
Units: 4-0-2
______
Uses case studies to investigate the macroeconomic environment in which firms operate. First half of subject develops the basic tools of macroeconomic management: monetary, fiscal, and exchange rate policy. Discusses recent emerging market and financial crises, examining their causes, how best to address them, and how to prevent them from recurring in the future. Second half evaluates different strategies of economic development. Topics include growth, the role of debt and foreign aid, and the reliance on natural resources.
Staff

15.013 Industrial Economics for Strategic Decisions
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 15.010 or 15.011
Units: 3-0-9
______
Applies principles of industrial economics most relevant for corporate strategy to analysis of particular industries. Topics include market structure and its determinants; rational strategic behavior in small numbers situations; strategies for price and nonprice competition; dynamic pricing, output, and advertising decisions; entry and entry deterrence; competition with network externalities; investments under uncertainty; R&D and patent licensing; and the growth and evolution of industries.
R. Pindyck
No textbook information available

15.014 Applied Macro- and International Economics II
______

Graduate (Spring); second half of term
Prereq: 15.012 or 15.015
Units: 4-0-2
______
Establishes understanding of the development processes of societies and economies. Studies several dimensions of sustainability (environmental, social, political, institutional, economy, organizational, relational, and personal) and the balance among them. Explores the basics of governmental intervention, focusing on areas such as the judicial system, environment, social security, and health. Builds skills to determine what type of policy is most appropriate. Considers implications of new technologies on the financial sector: internationalization of currencies, mobile payment systems, and cryptocurrencies. Discusses the institutional framework to ensure choices are sustainable across all dimensions and applications.
R. Rigobon

15.015 Macro and International Economics
______

Graduate (Fall); first half of term
Prereq: Permission of instructor
Units: 2-0-4
Ends Oct 21. Lecture: TR8.30-10 (E51-395) or TR10-11.30 (E51-395)
______
Focuses on the policy and economic environment of firms. Subject divided in two parts: study of the closed economy and how monetary and fiscal policy interacts with employment, GNP, inflation, and interest rates; and study of the open economy with discussion of recent financial and currency crises in developed and emerging markets. Restricted to Sloan Fellows.
A. Cavallo
No required or recommended textbooks

15.021[J] Real Estate Economics
______

Graduate (Fall)
(Same subject as11.433[J])
Prereq: 14.01, 15.010, or 15.011
Units: 4-0-8
Lecture: TR11-12.30 (4-270) Recitation: M9-10.30 (9-354) +final
______
Develops understanding of the fundamental economic factors that shape the market for real property, as well as the influence of capital markets in asset pricing. Analyzes of housing as well as commercial real estate. Covers demographic analysis, regional growth, construction cycles, urban land markets, and location theory. Exercises and modeling techniques for measuring and predicting property demand, supply, vacancy, and prices.
W. C. Wheaton
Textbooks (Fall 2016)

15.023[J] Global Climate Change: Economics, Science, and Policy
______

Graduate (Spring)
(Same subject as12.848[J])
(Subject meets with12.348[J],15.026[J])
Prereq: Calculus II (GIR); 5.60; 14.01 or 15.010; or permission of instructor
Units: 3-0-6
______
Introduces scientific, economic, and ecological issues underlying the threat of global climate change, and the institutions engaged in negotiating an international response. Develops an integrated approach to analysis of climate change processes, and assessment of proposed policy measures, drawing on research and model development within the MIT Joint Program on the Science and Policy of Global Change. Graduate students are expected to explore the topic in greater depth through reading and individual research.
R. G. Prinn

15.024 Applied Economics for Managers
______

Graduate (Summer)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.722
______
Develops facility with concepts, language, and analytical tools of economics. Primary focus on microeconomics, analysis of markets and strategic interactions among firms. Emphasizes integration of theory, data, and judgment in the analysis of corporate decisions, and in the assessment of the changing global business environment. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
T. Stoker
No textbook information available

15.025 Game Theory for Strategic Advantage
______

Graduate (Spring)
(Subject meets with15.0251)
Prereq: 15.010, 15.011, 15.015, or 14.01
Units: 3-0-6
______
Develops and applies principles of game theory relevant to managers' strategic decisions. Topics include how to reason about strategies and opponents; strategic commitment, reputation, and "irrational" actions; brinkmanship and negotiation; auctions; and the design of markets and contests. Applications to a variety of business decisions that arise in different industries, both within and outside the firm. Meets with 15.0251 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
A. Bonatti

15.0251 Game Theory for Strategic Advantage
______

Undergrad (Spring)
(Subject meets with15.025)
Prereq: 15.0111 or 14.01
Units: 3-0-6
______
Develops and applies principles of game theory relevant to managers' strategic decisions. Topics include how to reason about strategies and opponents; strategic commitment, reputation, and "irrational" actions; brinkmanship and negotiation; auctions; and the design of markets and contests. Applications to a variety of business decisions that arise in different industries, both within and outside the firm. Meets with 15.025 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
A. Bonatti

15.026[J] Global Climate Change: Economics, Science, and Policy
______

Undergrad (Spring)
(Same subject as12.348[J])
(Subject meets with12.848[J],15.023[J])
Prereq: Calculus II (GIR); 5.60; 14.01 or 15.010; or permission of instructor
Units: 3-0-6
______
Introduces scientific, economic, and ecological issues underlying the threat of global climate change, and the institutions engaged in negotiating an international response. Develops an integrated approach to analysis of climate change processes, and assessment of proposed policy measures, drawing on research and model development within the MIT Joint Program on the Science and Policy of Global Change. Graduate students are expected to explore the topic in greater depth through reading and individual research. 12.340 recommended.
R. G. Prinn

15.031[J] Energy Decisions, Markets, and Policies
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject as11.161[J],14.43[J],17.397[J],21A.415[J])
Prereq: 14.01, 15.0111, or permission of instructor
Units: 4-0-8
______
Structured around choices and constraints regarding sources and uses of energy by households, firms, and governments, introduces managerial, economic, political, social and cultural frameworks for describing and explaining behavior at various levels of aggregation. Includes examples of cost-benefit, organizational and institutional analyses of energy generation, distribution, and consumption. Topics include the role of markets and prices; financial analysis of energy-related investments; institutional path dependence; economic and political determinants of government regulation and the impact of regulation on decisions; and other forms of government action and social norms regarding desired behavior and opportunities for businesses and consumers, including feedback into the political/regulatory system. Examples drawn from a wide range of countries and settings.
C. Warshaw

15.032[J] Engineering, Economics and Regulation of the Electric Power Sector
______

Graduate (Spring)
(Same subject as6.695[J],IDS.505[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Provides an in-depth and interdisciplinary look at electric power systems, focusing on regulation as the link among engineering, economic, legal, and environmental viewpoints. Topics include electricity markets, incentive regulation of network utilities, retail competition, tariff design, distributed generation, rural electrification, multinational electricity markets, environmental impacts, future of utilities and strategic sustainability issues under both traditional and competitive regulatory frameworks. Background in policy, microeconomics, or engineering desirable.
C. Vergara

15.034 Metrics for Managers
______

Graduate (Fall)
(Subject meets with15.0341)
Prereq: None
Units: 4-0-5
Lecture: TR2.30-4 (E51-335) Recitation: M2.30 (E51-149)
______
Enables students to evaluate the quality of evidence supported by data and to implement an empirical toolkit that provides credible answers to questions in finance, marketing, human resources, strategy, and general business planning. Uses econometrics as the underlying framework to develop deep understanding of regression modelling and its insights for data analytics using big and small data. Focuses primarily on empirical work conducted by students via in-class labs, problem sets, and projects. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. Doyle, R. Rigobon
No required or recommended textbooks

15.0341 Metrics for Managers
______

Undergrad (Fall)
(Subject meets with15.034)
Prereq: None
Units: 4-0-5
Lecture: TR2.30-4 (E51-335) Recitation: M2.30 (E51-149)
______
Enables students to evaluate the quality of evidence supported by data and to implement an empirical toolkit that provides credible answers to questions in finance, marketing, human resources, strategy, and general business planning. Uses econometrics as the underlying framework to develop deep understanding of regression modelling and its insights for data analytics using big and small data. Focuses primarily on empirical work conducted by students via in-class labs, problem sets, and projects. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. Doyle, R. Rigobon
No required or recommended textbooks

15.037[J] Energy Economics and Policy
______

Undergrad (Spring) HASS Social Sciences
(Same subject as14.44[J])
Prereq: 14.01
Units: 4-0-8
Credit cannot also be received for14.444,15.038
______
Analyzes business and public policy issues in energy markets and in the environmental markets to which they are closely tied. Examines the economic determinants of industry structure and evolution of competition among firms in these industries. Investigates successful and unsuccessful strategies for entering new markets and competing in existing markets. Industries studied include oil, natural gas, coal, electricity, and transportation. Topics include climate change and environmental policy, the role of speculation in energy markets, the political economy of energy policies, and market power and antitrust. Two team-based simulation games, representing the world oil market and a deregulated electricity market, act to cement the concepts covered in lecture. Students taking graduate version complete additional assignments. Limited to 60.
C. Knittel

15.038[J] Energy Economics and Policy
______

Graduate (Spring)
(Same subject as14.444[J])
Prereq: 14.01
Units: 4-0-8
Credit cannot also be received for14.44,15.037
______
Theoretical and empirical perspectives on individual and industrial demand for energy, energy supply, energy markets, and public policies affecting energy markets. Discusses aspects of the oil, natural gas, electricity, and nuclear power sectors. Examines energy tax, price regulation, deregulation, energy efficiency and policies for controlling pollution and CO2 emissions. Students taking the graduate version complete additional assignments. Limited to 60.
C. Knittel

15.040 Seminar in Managerial Economics
______

Graduate (Spring) Can be repeated for credit
Prereq: 15.010, 15.012
Units arranged
______
Group study of current topics related to managerial economics.
T. M. Stoker

Operations Research/Statistics

15.053 Optimization Methods in Business Analytics
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: None
Units: 4-0-8
______
Introduces optimization methods with a focus on modeling, solution techniques, and analysis. Covers linear programming, network optimization, integer programming, and nonlinear programming. Applications to logistics, manufacturing, data analysis, transportation, marketing, project management, and finance. Includes a project in which student teams select and solve an optimization problem (possibly a large-scale problem) of practical interest.
J. Orlin

15.054[J] The Airline Industry
______

Graduate (Fall)
(Same subject as1.232[J],16.71[J])
Prereq: None
Units: 3-0-9
Lecture: MW1-2.30 (35-225)
______
Overview of the global airline industry, focusing on recent industry performance, current issues and challenges for the future. Fundamentals of airline industry structure, airline economics, operations planning, safety, labor relations, airports and air traffic control, marketing, and competitive strategies, with an emphasis on the interrelationships among major industry stakeholders. Recent research findings of the MIT Global Airline Industry Program are showcased, including the impacts of congestion and delays, evolution of information technologies, changing human resource management practices, and competitive effects of new entrant airlines. Taught by faculty participants of the Global Airline Industry Program.
P. P. Belobaba, A. I. Barnett, C. Barnhart, R. J. Hansman, T. A. Kochan
Textbooks (Fall 2016)

15.060 Data, Models, and Decisions
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.730
Lecture: MW8.30-10 (E62-262, E51-335, E62-223) or MW10-11.30 (E62-262, E51-335, E62-223) Recitation: R4 (E62-233) or W3 (E52-164, E51-149, E62-233) or R3 (E62-233) or R1 (E62-276) +final
______
Introduces students to the basic tools in using data to make informed management decisions. Covers introductory probability, decision analysis, basic statistics, regression, simulation, linear and nonlinear optimization, and discrete optimization. Computer spreadsheet exercises, cases, and examples drawn from marketing, finance, operations management, and other management functions. Restricted to first-year Sloan master's students.
D. Bertsimas, R. Freund, G. Perakis, A. S. Schulz
No textbook information available (Summer 2016); Textbooks (Fall 2016)

15.062[J] Data Mining: Finding the Data and Models that Create Value
______

Graduate (Fall); second half of term
(Same subject asIDS.145[J])
(Subject meets with15.0621)
Prereq: 15.060 or 15.075
Units: 2-0-4
Begins Oct 31. Lecture: MW4-5.30 (E51-345) Recitation: T4 (E51-315)
______
Provides an introduction to data mining and machine learning, a class of methods that assist in recognizing patterns and making intelligent use of massive amounts of data collected via the internet, e-commerce, electronic banking, point-of-sale devices, bar-code readers, medical databases, search engines, and social networks. Includes topics in logistic regression, association rules, tree-structured classification and regression, cluster analysis, discriminant analysis, and neural network methods. Presents examples of successful applications in areas such as credit ratings, fraud detection, marketing, customer relationship management, and investments. Introduces data-mining software. Term project required. Meets with 15.0621 when offered concurrently. Students taking graduate version complete additional assignments.
R. E. Welsch
Textbooks (Fall 2016)

15.0621 Data Mining: Finding the Data and Models that Create Value
______

Undergrad (Fall); second half of term
(Subject meets with15.062[J],IDS.145[J])
Prereq: 15.075
Units: 2-0-4
Begins Oct 31. Lecture: MW4-5.30 (E51-345) Recitation: T4 (E51-315)
______
Provides an introduction to data mining and machine learning, a class of methods that assist in recognizing patterns and making intelligent use of massive amounts of data collected via the internet, e-commerce, electronic banking, point-of-sale devices, bar-code readers, medical databases, search engines, and social networks. Includes topics in logistic regression, association rules, tree-structured classification and regression, cluster analysis, discriminant analysis, and neural network methods. Presents examples of successful applications in areas such as credit ratings, fraud detection, marketing, customer relationship management, and investments. Introduces data-mining software. Term project required. Meets with 15.062 when offered concurrently. Students taking graduate version complete additional assignments.
R. E. Welsch
Textbooks (Fall 2016)

15.064[J] Engineering Probability and Statistics
______

Graduate (Summer)
(Same subject asIDS.210[J])
Prereq: Calculus II (GIR)
Units: 4-0-8
______
Modeling and analysis of uncertainty and variation. Covers probability models and distributions, regression, and basic statistical procedures pertinent to manufacturing and operations. Introduces experimental and robust design, statistical process control, forecasting, and data-mining. Students use a data analysis package, such as JMP, Minitab, or MATLAB. Primarily for Leaders for Global Operations students.
A. I. Barnett, R. E. Welsch
No textbook information available

15.066[J] System Optimization and Analysis for Operations
______

Graduate (Summer)
(Same subject as2.851[J])
Prereq: Calculus II (GIR)
Units: 4-0-8
______
Introduction to mathematical modeling, optimization, and simulation, as applied to manufacturing. Specific methods include linear programming, network flow problems, integer and nonlinear programming, discrete-event simulation, heuristics and computer applications for manufacturing processes and systems. Restricted to Leaders for Global Operations students.
V. Farias
No textbook information available

15.068 Statistical Consulting
______

Graduate (Fall, Spring)
Prereq: 15.060
Units: 3-0-6
Lecture: MW4-5.30 (E51-145)
______
Addresses statistical issues as a consultant would face them: deciphering the client's question; finding appropriate data; performing a viable analysis; and presenting the results in compelling ways. Real-life cases and examples.
A. I. Barnett
Textbooks (Fall 2016)

15.070[J] Advanced Stochastic Processes
______

Graduate (Spring)
(Same subject as6.265[J])
Prereq: 6.431B, 15.085J, 18.100A, 18.100B, or 18.100Q
Units: 3-0-9
______
Analysis and modeling of stochastic processes. Topics include measure theoretic probability, martingales, filtration, and stopping theorems; elements of large deviations theory; Brownian motion and reflected Brownian motion; stochastic integration and Ito calculus; functional limit theorems. Applications to finance theory, insurance, queueing and inventory models.
D. Gamarnik, G. Bresler

15.071 The Analytics Edge
______

Graduate (Spring)
(Subject meets with15.0711)
Prereq: 15.053 or 15.060
Units: 4-0-8
______
Presents real-world examples in which quantitative methods provide a significant competitive edge that has led to a first order impact on some of today's most important companies. Examples include finance (quantitative asset management and options pricing), sports, health care, revenue management, supply chains, and the Internet. Outlines the competitive landscape. Presents the key quantitative methods that created the edge (data-mining, dynamic optimization, simulation), and discusses their impact. Uses R programming language. Includes team projects. Meets with 15.0711 when offered concurrently. Students taking graduate version complete additional assignments.
D. Bertsimas

15.0711 The Analytics Edge
______

Undergrad (Spring)
(Subject meets with15.071)
Prereq: 15.053
Units: 4-0-8
______
Presents real-world examples in which quantitative methods provide a significant competitive edge that has led to a first order impact on some of today's most important companies. Examples include finance (quantitative asset management and options pricing), sports, health care, revenue management, supply chains, and the Internet. Outlines the competitive landscape. Presents the key quantitative methods that created the edge (data-mining, dynamic optimization, simulation), and discusses their impact. Uses R programming language. Includes team projects. Meets with 15.071 when offered concurrently. Students taking graduate version complete additional assignments.
D. Bertsimas

15.073[J] Logistical and Transportation Planning Methods
______

Graduate (Spring)
(Same subject as1.203[J],16.76[J])
Prereq: 6.041B
Units: 3-0-9
______
Quantitative techniques of operations research with emphasis on applications in transportation systems analysis (urban, air, ocean, highway, and pickup and delivery systems) and in the planning and design of logistically oriented urban service systems (e.g., fire and police departments, emergency medical services, and emergency repair services). Unified study of functions of random variables, geometrical probability, multi-server queuing theory, spatial location theory, network analysis and graph theory, and relevant methods of simulation. Computer exercises and discussions of implementation difficulties.
R. C. Larson, A. I. Barnett

15.074[J] Predictive Data Analytics and Statistical Modeling
______

Graduate (Spring)
(Same subject asIDS.213[J])
Prereq: 6.431, 15.060, or permission of instructor
Units: 4-0-5
Credit cannot also be received for15.0741
______
Provides a brief review of statistics and regression drawn from advanced topics, such as bootstrap resampling, variable selection, data and regression diagnostics, visualization, and Bayesian and robust methods. Covers data-mining and machine learning, including classification, logistic regression, and clustering. Culminates with time series analysis and forecasting, design of experiments, analysis of variance, and process control. Uses statistical computing systems based on application add-ins and stand-alone packages. Case studies involve finance, management science, consulting, risk management, and engineering systems. Term project required. Meets with 15.0741 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details
R. E. Welsch

15.0741 Predictive Data Analytics and Statistical Modeling
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 6.041B
Units: 4-0-5
Credit cannot also be received for15.074,IDS.213
______
Provides a brief review of statistics and regression drawn from advanced topics, such as bootstrap resampling, variable selection, data and regression diagnostics, visualization, and Bayesian and robust methods. Covers data-mining and machine learning, including classification, logistic regression, and clustering. Culminates with time series analysis and forecasting, design of experiments, analysis of variance, and process control. Uses statistical computing systems based on application add-ins and stand-alone packages. Case studies involve finance, management science, consulting, risk management, and engineering systems. Term project required. Meets with 15.074 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
R. E. Welsch

15.075[J] Statistical Thinking and Data Analysis
______

Undergrad (Spring) Institute Lab
(Same subject asIDS.013[J])
Prereq: 6.041B or 15.079
Units: 3-1-8
______
Introduces a rigorous treatment of statistical data analysis while helping students develop a strong intuition for the strengths and limitations of various methods. Topics include statistical sampling and uncertainty, estimation, hypothesis testing, linear regression, classification, analysis of variation, and elements of data mining. Involves empirical use of hypothesis testing and other statistical methodologies in several domains, including the assessment of A-B experiments on the web and the identification of genes correlated with diseases.
R. Mazumder

15.077[J] Statistical Learning and Data Mining
______

Graduate (Spring)
(Same subject asIDS.211[J])
Prereq: 6.431, 15.085, or 18.600; 18.06 or 18.700
Units: 4-0-8
______
Advanced introduction to the theory and application of statistics, data-mining, and machine learning, concentrating on techniques used in management science, marketing, finance, consulting, engineering systems, and bioinformatics. First half builds the statistical foundation for the second half, with topics selected from sampling, including the bootstrap, theory of estimation, testing, nonparametric statistics, analysis of variance, categorical data analysis, regression analysis, MCMC, EM, Gibbs sampling, and Bayesian methods. Second half focuses on data mining, supervised learning, and multivariate analysis. Topics selected from logistic regression; principal components and dimension reduction; discrimination and classification analysis, including trees (CART), partial least squares, nearest neighbors, regularized methods, support vector machines, boosting and bagging, clustering, independent component analysis, and nonparametric regression. Uses statistics software packages, such as R and MATLAB for data analysis and data mining. Includes a term project.
R. E. Welsch

15.079 Introduction to Applied Probability
______

Graduate (Fall)
(Subject meets with15.0791)
Prereq: Calculus I (GIR)
Units: 4-0-8
Lecture: MW1-2.30 (E51-372) +final
______
Presents probability from the perspective of applied mathematics, with strong emphasis on an intuitive overview of key theorems and continuing demonstrations of their usefulness. Covers the laws of probability and numerous important discrete and continuous random variables, both individually and in combination. Introduces simulation. Draws applications from economics, finance, engineering, marketing, public policy, operations management, and operations research. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
A. Barnett, R. Larson
Textbooks (Fall 2016)

15.0791 Introduction to Applied Probability
(New)
______

Undergrad (Fall) Rest Elec in Sci & Tech
(Subject meets with15.079)
Prereq: Calculus I (GIR)
Units: 4-0-8
Lecture: MW1-2.30 (E51-372) +final
______
Presents probability from the perspective of applied mathematics, with strong emphasis on an intuitive overview of key theorems and continuing demonstrations of their usefulness. Covers the laws of probability and numerous important discrete and continuous random variables, both individually and in combination. Introduces simulation. Draws applications from economics, finance, engineering, marketing, public policy, operations management, and operations research. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
A. Barnett, R. Larson
Textbooks (Fall 2016)

15.081[J] Introduction to Mathematical Programming
______

Graduate (Fall)
(Same subject as6.251[J])
Prereq: 18.06
Units: 4-0-8
Lecture: TR1-2.30 (32-155) Recitation: F10 (36-156) or F12 (32-144)
______
Introduction to linear optimization and its extensions emphasizing both methodology and the underlying mathematical structures and geometrical ideas. Covers classical theory of linear programming as well as some recent advances in the field. Topics: simplex method; duality theory; sensitivity analysis; network flow problems; decomposition; integer programming; interior point algorithms for linear programming; and introduction to combinatorial optimization and NP-completeness.
J. N. Tsitsiklis, D. Bertsimas
Textbooks (Fall 2016)

15.082 Network Optimization
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 15.081 or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Doctoral-level subject on network models and algorithms. Emphasizes design and analysis of efficient algorithms for network flow models. Topics may vary from year to year.
J. Orlin

15.083[J] Integer Programming and Combinatorial Optimization
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as6.859[J])
Prereq: 15.081J or permission of instructor
Units: 4-0-8
______
In-depth treatment of the modern theory of integer programming and combinatorial optimization, emphasizing geometry, duality, and algorithms. Topics include formulating problems in integer variables, enhancement of formulations, ideal formulations, integer programming duality, linear and semidefinite relaxations, lattices and their applications, the geometry of integer programming, primal methods, cutting plane methods, connections with algebraic geometry, computational complexity, approximation algorithms, heuristic and enumerative algorithms, mixed integer programming and solutions of large-scale problems.
D. J. Bertsimas, A. S. Schulz

15.084[J] Nonlinear Optimization
______

Graduate (Spring)
(Same subject as6.252[J])
Prereq: 18.06; 18.100A, 18.100B, or 18.100C
Units: 4-0-8
______
Unified analytical and computational approach to nonlinear optimization problems. Unconstrained optimization methods include gradient, conjugate direction, Newton, sub-gradient and first-order methods. Constrained optimization methods include feasible directions, projection, interior point methods, and Lagrange multiplier methods. Convex analysis, Lagrangian relaxation, nondifferentiable optimization, and applications in integer programming. Comprehensive treatment of optimality conditions and Lagrange multipliers. Geometric approach to duality theory. Applications drawn from control, communications, power systems, and resource allocation problems.
R. M. Freund, D. P. Bertsekas, G. Perakis

15.085[J] Fundamentals of Probability
______

Graduate (Fall)
(Same subject as6.436[J])
Prereq: Calculus II (GIR)
Units: 4-0-8
Lecture: MW2.30-4 (E51-345) Recitation: F2 (66-144) +final
______
Introduction to probability theory. Probability spaces and measures. Discrete and continuous random variables. Conditioning and independence. Multivariate normal distribution. Abstract integration, expectation, and related convergence results. Moment generating and characteristic functions. Bernoulli and Poisson process. Finite-state Markov chains. Convergence notions and their relations. Limit theorems. Familiarity with elementary notions in probability and real analysis is desirable.
J. N. Tsitsiklis, D. Gamarnik
Textbooks (Fall 2016)

15.089 Analytics Capstone
(New)
______

Graduate (IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
______
Practical application of business analytics problems within a real company. Teams of 1-2 students, matched with company projects, visit companies to define project and scope. In class, students refine and improve on projects and devise methods for solving problems for their select companies. Mentors are assigned to each team. The culmination of the program is summer, on-site, practical training. Restricted to Master of Business Analytics students.
D. Bertsimas

15.093[J] Optimization Methods
______

Graduate (Fall)
(Same subject as6.255[J],IDS.200[J])
Prereq: 18.06
Units: 4-0-8
Lecture: TR2.30-4 (32-123) Recitation: W3 (66-168) or F1 (66-144) +final
______
Introduces the principal algorithms for linear, network, discrete, robust, nonlinear, dynamic optimization and optimal control. Emphasizes methodology and the underlying mathematical structures. Topics include the simplex method, network flow methods, branch and bound and cutting plane methods for discrete optimization, optimality conditions for nonlinear optimization, interior point methods for convex optimization, Newton's method, heuristic methods, and dynamic programming and optimal control methods.
D. Bertsimas, P. Parrilo
Textbooks (Fall 2016)

15.094[J] Robust Modeling, Optimization, and Computation
______

Graduate (Spring)
(Same subject as1.142[J])
Prereq: 18.06 or permission of instructor
Units: 4-0-8
______
Introduces modern robust optimization, including theory, applications, and computation. Presents formulations and their connection to probability, information and risk theory for conic optimization (linear, second-order, and semidefinite cones) and integer optimization. Application domains include analysis and optimization of stochastic networks, optimal mechanism design, network information theory, transportation, pattern classification, structural and engineering design, and financial engineering. Students formulate and solve a problem aligned with their interests in a final project.
D. Bertsimas

15.096 Prediction: Machine Learning and Statistics
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Gives a practical background and theoretical foundation to machine learning algorithms and Bayesian analysis. Includes an overview of the top ten algorithms in data mining. Covers frameworks for knowledge discovery, a unified view of support vector machines, AdaBoost and regression based on regularized risk minimization; generalization bounds from statistical learning theory based on covering numbers, VC dimension, and the margin theory; as well as basic Bayesian analysis and notes on the history of machine learning and statistics.
C. Rudin

15.097 Seminar in Statistics and Data Analysis
______

Graduate (Spring)
Prereq: Permission of instructor
Units arranged
______
Group study of current topics related to statistics and data analysis.
C. Rudin

15.098 Seminar in Applied Probability and Stochastic Processes
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: 6.431B
Units: 2-0-4
______
Doctoral student seminar covering current topics in applied probability and stochastic processes.
D. Gamarnik, D. Shah

15.099 Seminar in Operations Research
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 15.081J
Units arranged
Lecture: F10-12 (E62-550)
______
Doctoral student seminar covering current topics related to operations research.
D. Bertsimas, R. Freund, T. L. Magnanti, J. Orlin, G. Perakis, A. S. Schulz
No textbook information available

For additional related subjects in Statistics, see:

Civil and Environmental Engineering: 1.151, 1.155, 1.202, 1.203, and 1.205

Electrical Engineering and Computer Science: 6.041, 6.231, 6.245, 6.262, 6.431, and 6.435

Management: 15.034, 15.070, 15.075, and 15.098

Mathematics: 18.05, 18.175, 18.177, 18.440, 18.443, 18.445, and 18.465

See also: 2.830, 5.70, 5.72, 7.02, 8.044, 8.08, 10.816, 11.220, 16.322, 22.38, HST.191, and MAS.622

Health Care Management

15.122[J] Critical Reading and Technical Assessment of Biomedical Information
______

Graduate (Spring); first half of term
(Same subject asHST.977[J])
Prereq: SB degree in Biological Science or permission of instructor
Units: 1-0-2
______
Gain experience in critical reading of scientific literature, including patents, journal articles and FDA labels, with an emphasis on analyzing clinical controversies and emerging technologies in subject areas that have been or could become sources of entrepreneurial activity. Students required to analyze a variety of topics in the scientific literature, including screening for and cost-effectiveness of early detection of cancer, therapeutic opportunities in oncology, evaluation of immunotoxins and antibody therapies, and new prospects for the treatment of autoimmune disorders. To support the discussion of these topics, outside experts may be invited to participate as facilitators.
S. Lapidus, J. Karp

15.124[J] Evaluating a Biomedical Business Concept
______

Graduate (Fall)
(Same subject asHST.973[J])
Prereq: None
Units: 3-0-6
Lecture: W2.30-5.30 (E25-119)
______
Involves critical analysis of new biomedical business ideas. Inventors or principals of early stage companies present their ideas and provide background material including scientific papers and patents. Student teams interact with the companies, potential customers, other stakeholders and experts to develop a series of analyses concerning the critical issues. Company and student presentations supplemented by topic-specific lectures and presentations by biomedical entrepreneurs. Enrollment limited.
R. J. Cohen
Textbooks (Fall 2016)

15.128[J] Revolutionary Ventures: How to Invent and Deploy Transformative Technologies
______

Graduate (Fall)
(Same subject as9.455[J],20.454[J],MAS.883[J])
Prereq: Permission of instructor
Units: 2-0-7
URL: http://neuro.media.mit.edu/classes/neuroven/
Lecture: R2-4 (E15-341)
______
Seminar on envisioning and building ideas and organizations to accelerate engineering revolutions. Focuses on emerging technology domains, such as neurotechnology, imaging, cryotechnology, gerontechnology, and bio-and-nano fabrication. Draws on historical examples as well as live case studies of existing or emerging organizations, including labs, institutes, startups, and companies. Goals range from accelerating basic science to developing transformative products or therapeutics. Each class is devoted to a specific area, often with invited speakers, exploring issues from the deeply technical through the strategic. Individually or in small groups, students prototype new ventures aimed at inventing and deploying revolutionary technologies.
J. Bonsen, J. Jacobson
No textbook information available

15.132[J] Medicine for Managers and Entrepreneurs Proseminar
______

Graduate (Spring)
(Same subject asHST.972[J])
Prereq: None
Units: 3-0-6
______
Provides students with basic business-oriented clinical and technological knowledge related to health, healthcare and medicine through engagements with clinical and industry experts. Each session focuses on a specific field of medicine. Speakers include a basic science and/or clinical expert and a CEO or other senior executive involved in cutting-edge innovation in each area.
R. J. Cohen

15.136[J] Principles and Practice of Drug Development
______

Graduate (Fall)
(Same subject as7.547[J],10.547[J],HST.920[J],IDS.620[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://hst-hu-mit.mit.edu/courses/HST920
Lecture: W EVE (3-6 PM) (1-190)
______
Description and critical assessment of the major issues and stages of developing a pharmaceutical or biopharmaceutical. Drug discovery, preclinical development, clinical investigation, manufacturing and regulatory issues considered for small and large molecules. Economic and financial considerations of the drug development process. Multidisciplinary perspective from faculty in clinical; life; and management sciences; as well as industry guests.
T. J. Allen, C. L. Cooney, S. N. Finkelstein, A. J. Sinskey, G. K. Raju
No textbook information available

15.137[J] Case Studies and Strategies in Drug Discovery and Development
______

Graduate (Spring)
(Same subject as7.549[J],20.486[J],HST.916[J])
Prereq: None
Units: 2-0-4
______
Aims to develop appreciation for the stages of drug discovery and development, from target identification, to the submission of preclinical and clinical data to regulatory authorities for marketing approval. Following introductory lectures on the process of drug development, students working in small teams analyze how one of four new drugs or drug candidates traversed the discovery/development landscape. For each case, an outside expert from the sponsoring drug company or pivotal clinical trial principal investigator provides guidance and critiques the teams' presentations to the class.
S. R. Tannenbaum, A. J. Sinskey, A. W. Wood

15.141[J] Economics of the Health Care Industries
______

Graduate (Spring)
(Same subject asHST.918[J])
Prereq: Permission of instructor
Units: 3-0-6
______
Focuses on economic issues in various health care and allied industries, such as the pharmaceutical, biotechnology, medical device, vaccine and diagnostic sectors. Addresses differences between health care and other industries; regulatory issues, in the US and globally, that involve establishment of the efficacy and cost-effectiveness of treatments; managing those who manage research and development; policies to incentivize research and development for neglected tropical diseases; strategic issues in global pricing and marketing; use of e-commerce and information technology; personalized/stratified medicines and diagnostic biomarkers; and formation and management of various alliances. Visiting speakers from academia, government, NGOs, and industry. Assignments include 4 to 6 essays.
J. Doyle

Global Economics & Management

15.218 Global Economic Challenges and Opportunities
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
______
Analyzes the causes, effects and policy responses to major global economic issues. Focuses on financial crises, beginning with historical examples in emerging markets and building up to recent crises. Also focuses on current economic debates and challenges facing countries around the world. Possible topics include unsustainable debt, European union, aging populations, global warming, inequality and poverty, oil and commodity markets, international institutions, and the implications of rapid growth in the BRICs (Brazil, Russia, India, and China) and "frontier" economies. Some background in international economics recommended.
A. Orphanides

15.220 New Models for Global Business
______

Not offered academic year 2016-2017Graduate (Fall); second half of term
Prereq: None
Units: 3-0-3
______
Explores international dimensions of strategic management, and equips students to design strategies and structures that work effectively in an increasingly complex world economy. Focuses on a range of industries, from technology-based firms with global roots to emerging market multinationals. Topics include managing and leveraging big data, social and peer-to-peer networks, technology, and talent across national borders to develop capabilities and enhance competitive advantage. Includes a final group project in which students apply class concepts to evaluate strategic options for a startup or established global company of their choice. No final exam.
V. Karplus

15.221 Global Strategy and Organization
______

Graduate (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Focuses on the international dimensions of strategy and organization, and provides a framework for formulating strategies in an increasingly complex world economy, and for making those strategies work effectively. Topics include the globalization of industries, the continuing role of country factors in competition, organization of multinational enterprises, building global networks, and the changing managerial tasks under conditions of globalization. Restricted to Sloan Fellows in Innovation and Global Leadership.
Staff

15.223 Global Markets, National Policies and the Competitive Advantages of Firms
______

Graduate (Fall, Spring); second half of term
Prereq: None
Units: 3-0-3
Begins Oct 31. Lecture: TR10-11.30 (E51-149) or TR1-2.30 (E51-149)
______
Examines opportunities and risks firms face in today's global market. Provides conceptual tools for analyzing how governments and social institutions influence economic competition among firms embedded in different national settings. Public policies and institutions that shape competitive outcomes are examined through cases and analytical readings on different companies and industries operating in both developed and emerging markets. Restricted to Sloan Fellows in Innovation and Global Leadership.
S. Johnson
No textbook information available

15.225 Economy and Business in Modern China and India: China Lab and India Lab
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Provides an integrated approach to analyze the economies of China and India through action learning. The classroom portion covers macro issues of China and India, project-related issues and personal and learning reflections. The onsite portion involves working with a host company in China or in India. Students work in teams to tackle a real world business problem with an entrepreneurial Chinese or Indian company and produce a final deliverable for the host company. Students are required to take a mid semester trip during SIP and Spring Break to China or India to work onsite with the host company. Past lab projects have included creating a business plan for fundraising, developing a new market strategy, and crafting financial models; the projects have included both for-profit and NGO projects. Limited to graduate students who participate in China Lab or India Lab.
J. Grant, Y. Huang, M. Jester

15.227 - 15.229 Seminar in International Management
______

Graduate (Spring) Can be repeated for credit
Prereq: None
Units arranged
______
Group study of current topics related to international business.
Staff

15.232 Business Model Innovation: Global Health in Frontier Markets
______

Graduate (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Examines how new approaches to operations, revenue, marketing, finance, and strategy enable improved health care in resource-limited settings across Africa, Latin America, and Asia. Draws on system dynamics, design thinking, and strategic analysis. Explores success and failure in innovative healthcare delivery. Analysis of novel business models draws on case studies, videos, industry reports, research, and guest speakers. Students present their assessments of innovative base-of-the-pyramid health enterprises that aim to do more with less. Students who have not taken at least three management or business classes must apply to the instructor for permission to enroll before the first day of class.
A. Sastry

15.233 Global Health Lab
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Pairs faculty-mentored student teams with enterprises on the front lines of health care delivery in sub-Saharan Africa and South Asia. Custom-designed projects in strategy, business model innovation, operations, marketing, and technology designed to tackle specific barriers identified by each partnering organization. Interactive cases, practical exercises, and conversations with experts, all designed to support project work before, during, and after an intensive two-week onsite collaboration with entrepreneurs, leaders, staff, and stakeholders. Assignments include a portfolio of host deliverables, a foundational toolkit designed to support each project, and a distillation of learning from the field. Enrolled students must be available to work on site in Africa or South Asia for the entire weeks of SIP and Spring Break. Preference to students who have taken 15.232. Admission by application and interview in the prior November and December. Graduate students only.
A. Sastry

15.248 Israel Lab: Startup Nation's Entrepreneurship and Innovation Ecosystem
(New)
______

Graduate (Fall, IAP); second half of term
Prereq: None
Units: 3-0-6
Lecture: T EVE (4-7 PM) (E52-164)
______
Practical study of Israel's innovation and entrepreneurial ecosystem. On-campus component provides context about the country and its social and geopolitical issues; also introduces entrepreneurship lessons and team dynamics. During IAP, student teams work at the Israeli host organizations on complex problems in critical areas, such as high-tech, biotech, clean technology, and communications, with an emphasis on early stage ventures and their growth. Restricted to graduate students.
J. Cohen, C. Ortiz
No textbook information available

15.249 Institutions, Society, and International Business
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: None
Units arranged
______
Advanced seminar in the study of international management. Covers major theoretical work and approaches to empirical research in the fields of national business systems and globalization, linking them to the core frameworks of strategy and organization theory. Restricted to doctoral students.
E. Obukhova

History, Environment and Ethics

15.268 Choice Points: Readings on the Exercise of Power and Responsibility
______

Graduate (Spring)
Prereq: None
Units: 3-0-6 [P/D/F]
______
Managerial power and responsibility. Examines conflicts between power and moral responsibility and the contexts for choice in dealing with a number of such problems. Readings are principally "classics" used to illustrate several enduring issues. Restricted to Sloan Fellows in Innovation and Global Leadership.
Consult S. Sacca

15.269 Leadership Stories: Literature, Ethics, and Authority
______

Graduate (Fall)
Prereq: None
Units: 3-0-6
Lecture: MW2.30-4 (E51-315)
______
Explores how we use story to articulate ethical norms. The syllabus consists of short fiction, novels, plays, feature films and some non-fiction. Major topics include leadership and authority, professionalism, the nature of ethical standards, social enterprise, and questions of gender, cultural and individual identity, and work/life balance. Materials vary from year to year, but past readings have included work by Robert Bolt, Michael Frayn, Timothy Mo, Wole Soyinka, H.D. Thoreau, and others; films have included Crouching Tiger, Hidden Dragon, Hotel Rwanda, The Descendants, Motorcycle Diaries, Three Kings, and others. Draws on various professions and national cultures, and is run as a series of moderated discussions, with students centrally engaged in the teaching process.
L. Hafrey
Textbooks (Fall 2016)

Communication

15.270 Ethical Practice: Leading Through Professionalism, Social Responsibility, and System Design
______

Graduate (Spring); partial term
Prereq: None
Units: 3-0-3
______
Introduction to ethics in business, with a focus on business management. Students explore theoretical concepts in business ethics, and cases representing the challenges they will likely face as managers. Opportunity to work with guest faculty as well as business and other professional practitioners. Individual sessions take the form of moderated discussion, with occasional short lectures from instructor.
L. Hafrey

15.276 Communicating with Data
______

Undergrad (Spring)
Prereq: None
Units: 3-0-9
______
Focuses on how to communicate data clearly and effectively in a variety of situations. Develops skills to deliver data-oriented communications in both oral and written formats. Students participate in self-assessments and peer feedback. Final project involves a team presentation on a complex topic. Instruction in written and oral communication provided throughout course.
M. Kazakoff, B. Shields

15.277 Seminar in Communications
______

Graduate (Spring) Can be repeated for credit
Prereq: None
Units arranged
______

15.278 Seminar in Communications
______

Graduate (Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
______
Group study of current topics related to communication.
J. Yates

15.279 Management Communication for Undergraduates
______

Undergrad (Fall, Spring)
Prereq: None
Units: 3-0-9
Lecture: TR11.30-1 (E51-361)
______
Develops writing, speaking, teamwork, interpersonal, and cross-cultural communication skills necessary for management professionals. Assignments include creating persuasive memos, writing in response to cases, and giving presentations. Major project involves the production of a team report and presentation on a topic of interest to a professional audience.
L. Breslow
Textbooks (Fall 2016)

15.280 Communication for Leaders
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-1-5
Credit cannot also be received for15.710
Lecture: TR1-2.30 (E62-223) or TR4-5.30 (E51-145, E51-325) or TR1-2.30 (E51-325, E51-145) or TR2.30-4 (E51-145, E51-325) or TR1-2.30 (E51-372) or TR2.30-4 (E51-372, E62-223) or TR4-5.30 (E51-372, E62-223) Lab: TBA
______
Students develop and polish communication strategies and methods through discussion, examples, and practice. Emphasizes writing and speaking skills necessary for effective leaders. Includes several oral and written assignments which are integrated with other subjects, and with career development activities, when possible. Schedule and curriculum coordinated with Organizational Processes. Mandatory one hour recitation in small groups. Restricted to first-year Sloan graduate students.
N. Hartman, R. Pittore, V. Healy-Tangney, K. Blackburn, M. Kazakoff, J.Yates, B. Shields
Textbooks (Fall 2016)

15.281 Advanced Leadership Communication
______

Graduate (Spring)
Prereq: 15.279, 15.280, or permission of instructor
Units: 3-0-6
______
Introduces interactive oral and interpersonal communication skills critical to leaders, including strategies for presenting to a hostile audience, running effective and productive meetings, active listening, and contributing to group decision-making. Includes team-run classes on chosen communication topics, and an individual analysis of leadership qualities and characteristics. Students deliver an oral presentation and an executive summary, both aimed at a business audience.
N. Hartman, K. Blackburn, B. Shields, J. Yates, V. Healy-Tangney

15.282 EnActing Leadership: Shakespeare and Performance
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
______
Uses Shakespeare to challenge students' views of leadership and provide them with a deeper understanding of their performance as a leader. While performing shortened versions of Shakespeare's plays, students consider the serious questions they raise about the nature of leadership, power, and ambition, and explore their own leadership presence. Uses acting to strengthen speaking ability and personal presence.
C. Kelly

15.284 Strategic Leadership Communication
(New)
______

Graduate (Fall); partial term
Prereq: None
Units: 3-0-3
Lecture: MW10-11.30 (ENDS OCT 21) (E62-221) or MW1-2.30 (BEGINS OCT 31) (E51-361)
______
Introduces the essentials of how individuals and organizations develop and implement effective communication strategies, focusing on persuasion, audience analysis, communicator credibility, message construction, and delivery. Includes oral presentations and writing assignments with feedback to help students improve their communication effectiveness. Provides instruction to create communication strategies, develop and present clearly organized and powerful presentations, expand personal oral delivery and writing styles, and enhance presentations through effective visual aids. Restricted to Sloan Fellows.
N. Hartman, L. Breslow
Textbooks (Fall 2016)

15.289 Doctoral Seminar: Communication Skills for Academics
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-3
______
Focuses on the communication skills needed for a career in academia. Topics include writing for academic journals, preparing and delivering conference papers and job talks, peer reviewing for journals and conferences, and teaching. Participants are expected to work on a written project and deliver an oral presentation based on their current research. Limited to 20; priority to Sloan doctoral students who have completed their first year.
J. Yates, L. Breslow


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Produced: 26-SEP-2016 05:10 PMFall 2016 Course 15: Management
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Course 15: Management
Fall 2016


Work and Organizational Studies

15.301 Managerial Psychology Laboratory
______

Undergrad (Fall, Spring) Institute Lab
Prereq: None
Units: 3-3-9
Lecture: MW11 (32-155) Lab: F11 (E51-151) or F11 (E51-057)
______
Surveys individual and social psychology and organization theory interpreted in the context of the managerial environment. Laboratory involves projects of an applied nature in behavioral science. Emphasizes use of behavioral science research methods to test hypotheses concerning decision-making, group behavior, and organizational behavior. Instruction and practice in communication includes report writing, team projects, and oral and visual presentation. 12 units may be applied to the General Institute Laboratory Requirement. Shares lectures with 15.310.
Fall:J. Carroll
Spring:P. Osterman
Textbooks (Fall 2016)

15.305 Leadership and Management
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Explores leadership from the military perspective taught by professors of military science from the Army, Navy and Air Force. Survey of basic principles for successfully managing and leading people, particularly in public service and the military. Develops skills in topics such as oral and written communication techniques, planning, team building, motivation, ethics, decision-making, and managing change. Relies heavily on interactive experiential classes with case studies, student presentations, role plays, and discussion. Also appropriate for non-management science majors.
Information: J. Camille, C. Prior

15.307 Leadership and Ethics
______

Graduate (Fall)
Prereq: None
Units: 2-0-0 [P/D/F]
Lecture: W4-5.30 (E62-250)
______
Foundations, pillars, principles and mantras of outstanding leadership introduced through in-class discussions and case studies presented by senior industry leaders (LGO and non-LGO alumni). Alumni also share their personal leadership experiences with the class. Leaders for Global Operations students only.
V. Erdekian
Textbooks (Fall 2016)

15.310 Managerial Psychology
______

Graduate (Fall, Spring)
Prereq: None
Units: 2-1-6
Lecture: MW11 (32-155) Recitation: F11 (E51-390, E51-372)
______
Surveys social psychology and organization theory as interpreted in the context of the managerial environment. Covers a number of diverse topics, including motivation and reward systems, social influence, groups and teams, leadership, power, organizational design and culture, and networks and communication patterns. Similar in content to 15.311; shares lectures with 15.301. Preference to non-Course 15 students.
Fall:J. Carroll
Spring:P. Osterman
Textbooks (Fall 2016)

15.311 Organizational Processes
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-3-4
Lecture: TR1-2.30 (E51-325) or TR2.30-4 (E51-325) or TR4-5.30 (E51-325, E62-223) or TR1-2.30 (E62-223) or TR2.30-4 (E62-223)
______
Enhances students' ability to take effective action in complex organizational settings by providing the analytic tools needed to analyze, manage, and lead the organizations of the future. Emphasizes the importance of the organizational context in influencing which individual styles and skills are effective. Employs a wide variety of learning tools, from experiential learning to the more conventional discussion of written cases. Centers on three complementary perspectives on organizations: the strategic design, political, and cultural "lenses" on organizations. Major team project to analyze an actual organizational change, with oral and written reports. Restricted to first-year Sloan master's students.
K. Kellogg, E. Apfelbaum, C. Turco
No required or recommended textbooks

15.312 Organizational Processes for Business Analytics
(New)
______

Undergrad (Fall)
Prereq: None
Units: 3-0-9
Lecture: TR2.30-4 (E62-221)
______
Develops appreciation for organizational dynamics and competence in navigating social networks, working in a team, demystifying rewards and incentives, leveraging the crowd, understanding change initiatives, and making sound decisions. Provides instruction and practice in written and oral communication through presentations, and interpersonal and group exercises.
R. Reagans, L. Breslow
No textbook information available

15.316 Building and Leading Effective Teams
______

Graduate (Summer)
Prereq: None
Units: 2-1-0 [P/D/F]
______
An intensive one-week introduction to leadership, teams, and learning communities. Introduction of concepts and use of a variety of experiential exercises to develop individual and team skills and develop supportive relationships within the Fellows class. Restricted to first-year Leaders for Global Operations students.
Consult J. S. Carroll
No textbook information available

15.317 Leadership and Organizational Change
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Course spans the entire two-year Leaders for Global Operations (LGO) program, with a focus on leadership that blends theory and practice. During their first summer in the program, students reflect on exemplary leaders' stories in cases, the arts, journalism, philosophy, and social science, and evaluate their own previous leadership experience. During the succeeding four semesters, they apply the lessons they have learned in class to their off-campus internship and other activities at Sloan, and intensively review that experience as they reach the end of the program. Classes take the form of moderated discussion, with the expectation that students will participate fully in each session; students also submit short, written deliverables throughout the program.
L. Hafrey
Textbooks (Summer 2016); No textbook information available (Fall 2016)

15.318 Discovering Your Leadership Signature
______

Graduate (Fall) Can be repeated for credit
Prereq: 15.311, 15.322, or permission of instructor
Units: 3-0-6
Credit cannot also be received for15.739
Lecture: TR10-11.30 (E62-221)
______
Provides the tools to better understand one's unique way of leading change, i.e. leadership signature. Involves intensive self-assessment and interactive exercises aimed to help students identify their key strengths and weaknesses and hone their leadership skills. Focuses on the individual leadership credo and techniques for building confidence and credibility. Students explore alternative approaches to leadership, compare and contrast various leadership styles, and look at a range of leadership capabilities.
D. Ancona
No required or recommended textbooks

15.320 Strategic Organizational Design
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
______
Focuses on effective organizational design in both traditional and innovative organizations, with special emphasis on innovative organizational forms that can provide strategic advantage. Topics include when to use functional, divisional, or matrix organizations; how IT creates new organizational possibilities; examples of innovative organizational possibilities, such as democratic decision-making, crowd-based organizations, internal resource markets, and other forms of collective intelligence. Team projects include inventing new possibilities for real organizations.
T. Malone

15.321 Improvisational Leadership: In-the-Moment Leadership Skills
______

Graduate (Fall, Spring); second half of term
Prereq: None
Units: 3-0-3
Begins Oct 31. Lecture: T EVE (4-7 PM) (E62-233)
______
Designed to provide a practical understanding of the skills of improvisation and their application to leadership. Examines the essential elements of successful leadership, including creativity, emotional intelligence, adaptability, and the capacity to develop effective influence strategies and build strong teams. Cultivates students' ability to respond to the unexpected with confidence and agility. Each class offers a highly experiential learning laboratory where students practice a wide variety of improvised business scenarios, interactive exercises, and simulations.
D. Giardella
Textbooks (Fall 2016)

15.322 Leading Organizations
______

Graduate (Fall); first half of term
Prereq: None
Units: 3-0-3 [P/D/F]
Credit cannot also be received for15.716
Ends Oct 21. Lecture: F8-12 (E51-335) or F1-5 (E51-335) Lab: F8-12 (E51-376) or F8-12 (E51-393) or F1-5 (E51-393) or F1-5 (E51-385) or F1-5 (E51-376) or F8-12 (E51-385) Recitation: F9.30-11.30 (E51-063) or F2.30-4.30 (E51-057) or F9.30-11.30 (E51-085) or F2.30-4.30 (E51-061, E51-390, E51-063)
______
Analyzes through lectures, discussions, and class exercises, the human processes underlying organizational behavior. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
J. Van Maanen
No textbook information available (Summer 2016); Textbooks (Fall 2016)

15.323 Leading from the Middle
______

Graduate (Spring); second half of term
Prereq: None
Units: 2-0-1 [P/D/F]
______
Students and Leaders for Global Operations (LGO) alumni develop and present case studies that focus on the challenges and opportunities of leading from positions in the middle of an organization. Restricted to Leaders for Global Operations program students.
L. Hafrey

15.324 Practical leadership
______

Graduate (Spring); second half of term
Prereq: None
Units: 3-0-3 [P/D/F]
______
Strengthens leadership capacities through feedback, reflection, and practice. Students use readings, role plays, experiential exercises, self-reflection, and reviews of their own videos, as well as focused coaching and feedback, to optimize their own leadership capabilities. Focuses on individual leadership growth. Culminates with submission of a written summary of students', reflections and experiences around leadership from throughout the term.
P. Bentley

15.325 Seminar in Leadership I
______

Graduate (Fall); second half of term
Prereq: None
Units: 2-0-1 [P/D/F]
Begins Oct 31. Lecture: M EVE (5.30-7 PM) (E51-325) or W EVE (5.30-7 PM) (E51-325)
______
Provides students opportunities to meet senior executives of private and public institutions, and discuss key management issues from the perspective of top management. Students prepare detailed briefings identifying and analyzing important management issues facing these organizations. Seminar includes a one week field trip to a domestic location. Restricted to MIT Sloan Fellows.
Consult S. Sacca
No textbook information available

15.326 Seminar in Leadership II
______

Graduate (Spring)
Prereq: 15.325
Units: 2-0-1 [P/D/F]
______
Continuation of subject 15.325 on the identification and analysis of important management issues. Students prepare briefings and meet with senior government and international leaders during field trips in selected international areas. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
S. Sacca

15.328 Seminar in Organizational Studies
______

Graduate (Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
______
No textbook information available

15.329 Seminar in Organizational Studies
______

Graduate (Spring) Can be repeated for credit
Prereq: None
Units arranged
______
Group study of current topics related to organizational studies.
Consult D. G. Ancona

15.339 Distributed Leadership Workshop
______

Graduate (IAP)
Prereq: None
Units: 2-0-4 [P/D/F]
______
Focuses on the key leadership capabilities needed in today's increasingly decentralized organizations: sense-making, relating, visioning, and inventing. Through conceptual discussions, small group exercises, and self-reflection, helps students understand leadership capabilities, evaluate their leadership strengths and weaknesses, articulate their values and aspirations, and practice developing leadership skills in interaction with class members.
D. Ancona, T. Malone, W. Orlikowski

15.341 Individuals, Groups, and Organizations
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Covers classic and contemporary theories and research related to individuals, groups, and organizations. Designed primarily for doctoral students in the Sloan School of Management who wish to familiarize themselves with research by psychologists, sociologists, and management scholars in the area commonly known as micro organizational behavior. Topics may include motivation, decision making, negotiation, power, influence, group dynamics, and leadership.
J. Curhan

15.342 Organizations and Environments
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: R8.30-11.30 (E62-446)
______
Provides an introduction to research in "organizations and environments," an interdisciplinary domain of inquiry drawing primarily from sociology, and secondarily from economics, psychology, and political science. Seeks to understand organizational processes and outcomes in the surrounding economic, cultural, and institutional context in which they are situated. Also provides an introduction to the main groups that together form the Behavioral Policy Sciences (BPS) area of MIT/Sloan, including economic sociology, organization studies, work and employment, strategic management, global management, and technology, innovation, and entrepreneurship. Consists of four modules taught by faculty from each of the four BPS groups, as well as integrative sessions taught by the main instructor. Preference to first-year doctoral students in BPS.
R. Reagans
No textbook information available

15.345 Doctoral Proseminar in Behavioral and Policy Sciences
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
______
A professional seminar for doctoral students to report on their research, work on their thesis proposals, and practice their job talks. Also addresses general professional issues such as publishing, searching for jobs, the academic career, etc.
J. Carroll

15.347 Doctoral Seminar in Research Methods I
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces the process of social research, emphasizing the conceptualization of research choices to ensure validity, relevance, and discovery. Includes research design and techniques of data collection as well as issues in the understanding, analysis, and interpretation of data.
M. Amengual

15.348 Doctoral Seminar in Research Methods II
______

Graduate (Fall)
Prereq: 15.347 or permission of instructor
Units: 3-0-6
Lecture: M EVE (3-6 PM) (E62-350)
______
Builds on 15.347 to examine contemporary social research methods in depth. Focuses on making students familiar with the most important quantitative methods (e.g., logit/probit models, models for ordinal and nominal outcomes, count models, event history models).
E. J. Castilla
Textbooks (Fall 2016)

Technology, Innovation and Entrepreneurship

15.350 Managing Technological Innovation and Entrepreneurship
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
______
Focuses on the challenges inherent in attempting to take advantage of both incremental innovation and more radical or breakthrough changes in products, processes and services. Highlights the importance of innovation to both new ventures and to large established firms and explores the organizational, economic and strategic problems that must be tackled to ensure innovation is a long term source of competitive advantage. Discussions and class presentations cover non- technical as well as technology-based innovation. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
Staff

15.356 Product and Service Development in the Internet Age
______

Graduate (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Traditional "in-house" innovation processes must be changed to benefit from emerging open-source innovation practices. Users are now increasingly developing their own b-to-b and b-to-c products. Course explains proven open innovation development methods such as crowdsourcing, innovation toolkits, tournaments and more. Includes visits from industry experts who present cases that illustrate the art required to implement each method.
E. A. von Hippel

15.357 Economics of Ideas, Innovation and Entrepreneurship
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: None
Units: 3-0-6
______
Advanced subject in the economics of technological change. Covers the micro-foundations of the knowledge production function (including the role of creativity and the impact of Science), the impact of institutions and strategic interaction on the commercialization of new technology, and the diffusion and welfare impact of ideas and technology. Includes a mixture and explicit comparisons of both theoretical and empirical research. Students should have adequate preparation in microeconomic theory and econometrics. Primarily for PhD students.
P. Azoulay, S. Stern

15.358 Software and Internet Entrepreneurship
______

Graduate (Spring)
Prereq: 15.900 or 15.902
Units: 3-0-6
______
Considers key strategic concepts, especially the distinction between being a product versus a services company, as well as a product versus a platform strategy. Reviews how software became a business (from early developments in services to the emergence of standardized products), and the transition to software as a service, and cloud computing. Studies critical techniques for managing sales and marketing, as well as product development and project management for software products. Examines how the business differs for various platforms - including new and traditional enterprise software, social media, internet video, and mobile competitors - as well as for entrepreneurs competing in these markets. Student teams help teach some weekly sessions and analyze emerging companies and sectors in team projects.
M. A. Cusumano, I. Sayeed

15.359[J] Innovation Engineering: Moving Ideas to Impact
(New)
______

Undergrad (Fall)
(Same subject as6.901[J])
Prereq: None
Units: 3-3-6
Lecture: TR9-10.30 (1-390)
______
Designed for students to gain the perspective of a Chief Technology Officer of a start-up, large corporation, or a not-for-profit. Details the innovation process, from an idea's inception through impact in the economy, regardless of organizational setting. Explores how solutions are developed to become ready for broader market deployment. Includes testing and development of the problem-solution fit, probing of solutions for robustness, and testing of both technical and operational scaling of proposed solutions. Examines the human aspects of innovation, specifically issues of team building and readiness. Considers the broader system for innovation, including the role of key stakeholders in shaping its success in order to arrive at an impactful solution. Addresses intellectual property, the effect of regulations and social and cultural differences across varied global markets, and the personal skillset necessary to align and manage these issues.
V. Bulovic, F. Murray
No textbook information available

15.360 Introduction to Technological Entrepreneurship
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-0-1
Lecture: W EVE (4-7 PM) (E62-233)
______
Provides an overview of entrepreneurial theory and practice for founding, developing and growing new enterprises, primarily but not exclusively focused on companies with a technological base. Weekly lectures and dinner discussion sessions by academic and practitioner faculty engaged in the MIT Entrepreneurship Program, supplemented by leaders of related MIT entrepreneurship activities, e.g., Trust Center for MIT Entrepreneurship, Technology Licensing Office, Deshpande Center, and Venture Mentoring Service, as well as successful entrepreneurs and venture capitalists. Includes student Open Mic presentations and discussion of new business ideas. Enrollment in ES.580, Silicon Valley Study Tour, for the following spring term required. No listeners; restricted to students in Sloan Entrepreneurship and Innovation (E&I) MBA track.
E. Roberts
No required or recommended textbooks

15.363[J] Strategic Decision Making in the Life Sciences
______

Graduate (Spring)
(Same subject asHST.971[J])
Prereq: None
Units: 3-0-6
______
Surveys key strategic decisions faced by managers, investors and scientists at each stage in the value chain of the life science industry. Aims to develop students' ability to understand and effectively assess these strategic challenges. Focuses on the biotech sector, with additional examples from the pharmaceutical and medical device sectors. Includes case studies, analytical models, and detailed quantitative analysis. Intended for students interested in building a life science company or working in the sector as a manager, consultant, analyst, or investor. Provides analytical background to the industry for biological and biomedical scientists, engineers and physicians with an interest in understanding the commercial dynamics of the life sciences or the commercial potential of their research.
J. Fleming, A. Zarur

15.364 Regional Entrepreneurship Acceleration Lab (REAL)
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.3641
______
Aimed at students seeking a research-based but action-oriented understanding of innovation ecosystems, such as Silicon Valley, Kendall Square/Massachusetts, and other sites across the globe. Provides a framework for analyzing these critical innovation economies. Outlines the design and delivery of policies and programs (e.g., accelerators, prizes, tax policy, immigration policy) intended to accelerate innovation-driven entrepreneurship. Takes a stakeholder perspective to examine the role of entrepreneurs, risk capital providers, large corporations, governments and universities in innovation-driven entrepreneurship. Meets with 15.364 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
P. Budden, F. Murray

15.3641 Regional Entrepreneurship Acceleration Lab (REAL)
(New)
______

Undergrad (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.364
______
Aimed at students seeking a research-based but action-oriented understanding of innovation ecosystems, such as Silicon Valley, Kendall Square/Massachusetts, and other sites across the globe. Provides a framework for analyzing these critical innovation economies. Outlines the design and delivery of policies and programs (e.g., accelerators, prizes, tax policy, immigration policy) intended to accelerate innovation-driven entrepreneurship. Takes a stakeholder perspective to examine the role of entrepreneurs, risk capital providers, large corporations, governments and universities in innovation-driven entrepreneurship. Meets with 15.364 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
P. Budden, F. Murray

15.366 Energy Ventures
______

Graduate (Fall)
Prereq: 15.910; 15.390 or 15.371; 10.391 or 10.579
Units: 3-0-9
Lecture: R EVE (5-8 PM) (32-124) Recitation: F10.30-12 (E40-160)
______
Project-based approach to innovation and venture creation in the energy sector. Explores how innovation and entrepreneurial concepts apply (or do not apply) to the significant opportunities in the industry. Working in teams, students create new ventures specifically for the energy sector. Lectures guide teams through key elements of their projects. Concurrent enrollment in 15.933 recommended.
W. Aulet, T. Hynes, F. O'Sullivan
No textbook information available

15.367[J] Healthcare Ventures
______

Graduate (Spring)
(Same subject asHST.978[J])
Prereq: 15.910; 15.390 or 10.391 or 10.579
Units: 3-0-9
______
Focuses on entrepreneurship, with emphasis on startups bridging digital health and high-tech. Explores US and global macro trends and case studies. Features lectures by leading healthcare entrepreneurs and venture investors, and provides practical experience in networking through team projects. Evaluation based on team participation and assignments, including two team presentations. Video conference facilities provided to facilitate remote participation by Executive MBA and traveling students. Enrollment by application only. Enrollment by application only
M. Gray, Z. Chu

15.369 Seminar in Corporate Entrepreneurship
______

Not offered academic year 2016-2017Graduate (Fall); partial term
Prereq: 15.310 or 15.311
Units: 3-0-3
Subject Cancelled Subject Cancelled
______
Addresses the practical challenges of making an established company entrepreneurial and examines various roles related to corporate entrepreneurship. Outside speakers complement faculty lectures. Topics may vary from term to term.
A. Kacperczyk, C. Kiefer

15.371[J] Innovation Teams
______

Graduate (Fall, Spring)
(Same subject as 10.807[J])
Prereq: 15.911 or permission of instructor
Units: 4-4-4
Lecture: W11-2 (32-144) Lab: F9-11.30 (32-155)
______
Students work in teams to develop commercialization strategies for innovative research projects generated in MIT laboratories. Projects cover critical aspects of commercialization, from selecting the target application and market for the technology to developing an intellectual property strategy and performing a competitive analysis. Instruction provided in communication and teamwork skills, as well as analysis of the challenges and benefits of technology transfer. Includes lectures, guest speakers, and extensive team coaching. Designed primarily for students in engineering, science, and management. Applications, resumes, and a brief statement of interest are required prior to registration.
F. Murray, L. Perez-Breva, N. Afeyan
No textbook information available

15.372 Experimental Innovation Lab
(New)
______

Graduate (Fall)
Prereq: None
Units: 3-3-3
Lecture: T2.30-5.30 (E51-361)
______
Develops the skills needed to run randomized experiments (from design through analysis) in business settings in order to help firms innovate and shape their strategy. Provides foundational knowledge related to the basic structure of a good experiment, analysis methods, randomization, and reasons why even well-planned experiments may fail. Working in small teams, students design, run, and present the results of randomized trials with partner companies. Application required.
D. Sull, N. Thompson
No required or recommended textbooks

15.373[J] Venture Engineering
______

Undergrad (Spring)
(Same subject as2.912[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Develops the capability to move from testing ideas to assembling a venture as a system comprised of technological, human, social, regulatory, managerial, and financial processes and flows that affect costs, revenues, and value. Begins with a focus on leadership, addressing key issues involved in recruiting and building a founder team and its early employees. Fosters understanding of financial resource needs for the new enterprise and methods for raising funds. Students engage in a venture planning activity in which they must demonstrate their understanding of the concepts covered in class.
F. Murray

15.375[J] Development Ventures
______

Graduate (Fall)
(Same subject asEC.731[J],MAS.665[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: R10-12 (E14-633)
______
Seminar on founding, financing, and building entrepreneurial ventures in developing nations. Challenges students to craft enduring and economically viable solutions to the problems faced by these countries. Cases illustrate examples of both successful and failed businesses, and the difficulties in deploying and diffusing products and services through entrepreneurial action. Explores a range of established and emerging business models, as well as new business opportunities enabled by innovations emerging from MIT labs and beyond. Students develop a business plan executive summary suitable for submission in the MIT $100K Entrepreneurship Competition's Accelerate Contest or MIT IDEAS.
J. Bonsen, A. Pentland, C. Breazeal
No textbook information available

15.376[J] Media Ventures
______

Graduate (Spring) Can be repeated for credit
(Same subject asMAS.664[J])
Prereq: None
Units: 3-0-6
______
Seminar surveys internal and external entrepreneurship, based on Media Lab technologies, to increase understanding of how digital innovations grow into societal change. Cases illustrate examples of both successful and failed businesses, as well as difficulties in deploying and diffusing products. Explores a range of business models and opportunities enabled by emerging Media Lab innovations. Students craft a business analysis for one of the featured technology innovations. Past analyses have become the basis for research publications, and new ventures. Particular focus on big data, mobile, and the use of personal data.
A. Pentland, J. Bonsen

15.377[J] Linked Data Ventures
______

Graduate (Spring)
(Same subject as6.932[J])
Prereq: 6.005, 6.033, or permission of instructor
Units: 3-0-9
______
Provides practical experience in the use and development of semantic web technologies. Focuses on gaining practical insight from executives and practitioners who use these technologies in their companies. Working in multidisciplinary teams, students complete a term project to develop a sustainable prototype. Concludes with a professional presentation, judged by a panel of experts, and a technical presentation to faculty.
T. Berners-Lee, L. Kagal, K. Rae, R. Sturdevant

15.378 Building an Entrepreneurial Venture: Advanced Tools and Techniques
______

Graduate (Fall, Spring)
(Subject meets with15.3781)
Prereq: Permission of instructor
Units: 3-1-8
Lecture: M EVE (6-9 PM) (E40-160)
______
Intensive, project-based subject intended for startup teams already working on building a new, high-impact venture. Applies advanced entrepreneurial techniques to build and iterate a venture in a time-compressed manner. Includes weekly coaching sessions with instructors and peers, as well as highly interactive and customized sessions that provide practical, in-depth coverage on key topics in entrepreneurship. Topics include venture creation, primary market research, product development, market adoption, team and culture, and scaling processes with constrained resources. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details. Application required; consult instructor. No listeners.
B. Aulet, J. Baum, E. Chen
No textbook information available

15.3781 Building an Entrepreneurial Venture: Advanced Tools and Techniques
______

Undergrad (Fall, Spring)
(Subject meets with15.378)
Prereq: 15.3901 or permission of instructor
Units: 3-1-8
Lecture: M EVE (6-9 PM) (E40-160)
______
Intensive, project-based subject intended for startup teams already working on building a new, high-impact venture. Applies advanced entrepreneurial techniques to build and iterate a venture in a time-compressed manner. Includes weekly coaching sessions with instructors and peers, as well as highly interactive and customized sessions that provide practical, in-depth coverage on key topics in entrepreneurship. Topics include venture creation, primary market research, product development, market adoption, team and culture, and scaling processes with constrained resources. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details. Application required; consult instructor. No listeners.
B. Aulet, J. Baum, E. Chen
No textbook information available

15.385 Social Innovation and Entrepreneurship
______

Graduate (Spring)
Prereq: 15.911
Units: 3-0-6
______
Students work individually or in teams to develop a business plan for an enterprise (for- or nonprofit) to solve a social problem. They also have the opportunity to develop their skills by working on an existing social venture. Examines the theory and practice of social entrepreneurship and innovation within various social issues and topics, including social impact markets, performance measurement, and theory of change. Students gain practical knowledge on how to identify potential social venture opportunities; develop skills and competencies for creating, developing and implementing ideas; and measure the success and value of a young enterprise.
Staff

15.386 Managing in Adversity
______

Graduate (Fall, Spring); second half of term
Prereq: None
Units: 3-0-3
Begins Oct 31. Lecture: TR10-11.30 (E51-345)
______
Develops the skills required for a CEO to deal with complex problems under highly adverse conditions. Cases and guest CEO speakers present real-life, high-adversity situations that students then deal with through role play. Focuses on how to quickly define issues, determine and evaluate options, and take critical and precipitous actions to address the situation. No listeners.
P. Kurzina
No textbook information available

15.387 Entrepreneurial Sales
______

Not offered academic year 2016-2017Graduate (Fall, Spring)
Prereq: None
Units: 3-0-9
______
Practical and tactical ins and outs of how to sell technical products to a sophisticated marketplace. How to build and manage a sales force; building compensation systems for a sales force, assigning territories, resolving disputes, and dealing with channel conflicts. Focus on selling to customers, whether through a direct salesforce, a channel salesforce, or building an OEM relationship.
L. Shipley

15.389 Global Entrepreneurship Lab
______

Graduate (Fall, IAP)
Prereq: None
Units: 2-0-10
Lecture: TR2.30-4 (E62-276) or TR4-5.30 (E62-276) Recitation: R12 (E62-223)
______
Practical study of the climate for innovation and determinants of entrepreneurial success. Teams of students work with top management in one company to gain experience in running and building a new enterprise. Focuses primarily on start-ups operating in emerging markets. Restricted to graduate students.
S. Johnson, M. Jester
No textbook information available

15.390 New Enterprises
______

Graduate (Fall, Spring)
(Subject meets with15.3901)
Prereq: None
Units: 2-1-6
Lecture: MW2.30-4 (E62-262) or MW4-5.30 (32-141)
______
Covers the process of identifying and quantifying market opportunities, then conceptualizing, planning, and starting a new, technology-based enterprise. Topics include opportunity assessment, the value proposition, the entrepreneur, legal issues, entrepreneurial ethics, the business plan, the founding team, seeking customers and raising funds. Students develop detailed business plans for a start-up. Intended for students who want to start their own business, further develop an existing business, be a member of a management team in a new enterprise, or better understand the entrepreneur and the entrepreneurial process. Meets with 15.3901 when offered concurrently.
W. Aulet, C. Catalini
No textbook information available

15.3901 New Enterprises
______

Undergrad (Fall, Spring)
(Subject meets with15.390)
Prereq: None
Units: 2-1-6
Lecture: MW2.30-4 (E62-262) or MW4-5.30 (32-141)
______
Covers the process of identifying and quantifying market opportunities, then conceptualizing, planning, and starting a new, technology-based enterprise. Topics include opportunity assessment, the value proposition, the entrepreneur, legal issues, entrepreneurial ethics, the business plan, the founding team, seeking customers, and raising funds. Students develop detailed business plans for a start-up. Intended for students who want to start their own business, further develop an existing business, be a member of a management team in a new enterprise, or better understand the entrepreneur and the entrepreneurial process. Meets with 15.390 when offered concurrently. Students taking graduate version complete additional assignments.
W. Aulet, C. Catalini
No textbook information available

15.392 Entrepreneurial Product Development and Marketing
______

Graduate (Spring); first half of term
Prereq: 15.371 or 15.390
Units: 3-0-3
______
Students develop and help market an innovation-driven product that may form the basis of an entrepreneurial start-up, but also could be part of a larger entity. Students use tools and techniques to effectively and efficiently drive product development (hardware or software) in a fast-paced environment, including how to iterate their way to product/market fit, how to generate interest in their start-up through the internet, and how to select the right business model for their market. Application required.
B. Halligan, P. English

15.394 Dilemmas in Founding New Ventures
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.3941
______
Explores key organizational decisions that have far-reaching consequences for founders and their ventures. Though a series of cases, readings, and simulations, students examine five founders' dilemmas: whether and when to found, whom to include in the founding team, how to allocate equity among co-founders, whether to involve external investors, and when and how to exit. Aims to equip students with tools and frameworks to help them understand the implications of early decisions, and to build enduring resources that enable the venture to execute even if the original plan changes substantially. Meets with 15.3941 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
M. Marx

15.3941 Dilemmas in Founding New Ventures
(New)
______

Undergrad (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.394
______
Explores key organizational decisions that have far-reaching consequences for founders and their ventures. Through a series of cases, readings, and simulations, students examine five founders' dilemmas: whether and when to found, whom to include in the founding team, how to allocate equity among co-founders, whether to involve external investors and when and how to exit. Aims to equip students with tools and frameworks to help them understand the implications of early decisions, and to build enduring resources that enable the venture to execute even if the original plan changes substantially. Meets with 15.394 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
M. Marx

15.395 Entrepreneurship Without Borders
______

Graduate (Fall); first half of term
Prereq: None
Units: 3-0-3
Ends Oct 21. Lecture: TR10-11.30 (E62-250)
______
Examines opportunities and problems for entrepreneurs globally, including Europe, Latin America, and Asia. Covers linkages between the business environment, the institutional framework, and new venture creation. Special focus on blockchain technology. In addition to discussing a range of global entrepreneurial situations, student groups pick one particular cluster on which to focus and to understand what further development would entail. Classroom interactions based primarily on case studies.
S. Johnson
No textbook information available

15.396 Seminar in Entrepreneurship
______

Graduate (Spring)
Prereq: None
Units arranged
______
Group study of current topics related to entrepreneurship.
W. Aulet

15.397 Seminar in Entrepreneurship
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Group study of current topics related to high-tech entrepreneurship.
Staff
No textbook information available

15.398 Corporations at the Crossroads: The CEO Perspective
______

Graduate (Spring)
Prereq: None
Units: 2-0-4
______
Focuses on the role of the CEO. Provides a unique opportunity for students to interact with some of the world's leading CEOs who are invited to participate in each class. Topics include the job of the CEO, corporate strategy, career learnings and advice. Emphasizes in particular how the CEO is reacting to critical crossroads.
P. Kurzina

15.399 Entrepreneurship Lab
______

Graduate (Fall, Spring)
Prereq: None
Units: 2-9-1
Lecture: T EVE (6-9 PM) (E51-325)
______
Project-based course, in which teams of students from MIT and Harvard work with startups on problems of strategic importance to the venture. Popular sectors include software, hardware, robotics, cleantech, life sciences. In addition to the regular MIT registration process, students should register at the course website one month before class to facilitate formation of student teams and matching of teams with startup companies.
C. Catalini, J. Dougherty
No textbook information available

Finance

15.401 Managerial Finance
______

Graduate (Fall, Spring)
Prereq: None
Units: 4-0-5
Credit cannot also be received for15.417
Lecture: MW10-11.30 (E51-149) or MW1-2.30 (E51-149) or MW10-11.30 (E51-395) or MW1-2.30 (E51-325, E62-223) Recitation: F2 (E51-149) or F1 (E51-149) or T1 (E62-233, E51-085) or T3 (E62-233) +final
______
Covers the fundamentals of modern financial analysis that are essential to any manager, entrepreneur, investor, or other business professional. Topics include valuation, risk analysis, personal and corporate investment decisions, and an introduction to security analysis and asset management. A prerequisite for all other finance electives offered by the Finance Group. Meets with 15.417 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
Consult K. Nixon
Textbooks (Fall 2016)

15.402 Corporate Finance
______

Graduate (Fall, Spring)
Prereq: 15.401
Units: 3-0-6
Credit cannot also be received for15.418
Lecture: MW10-11.30 (E62-276) or MW1-2.30 (E62-276) +final
______
Introduction to corporate financial management. Topics include capital budgeting, investment decisions and valuation; working capital management, security issues; dividend policy; optimal capital structure; and real options analysis. Meets with 15.418 when offered concurrently.
P. Asquith, A. Malenko
Textbooks (Fall 2016)

15.403 Introduction to the Practice of Finance
______

Graduate (Fall)
Prereq: None
Units: 2-0-1
Lecture: M EVE (4-6 PM) (E62-276)
______
Seminar exposes students to some of the basic institutions and practices of the financial industry. Includes panel discussions with representatives from leading financial institutions, MIT alumni currently engaged in the financial services sector, and leading industry vendors. Restricted to first-year Finance track MBA students.
J. Parsons
No required or recommended textbooks

15.414 Financial Management
______

Graduate (Summer)
Prereq: 15.511
Units: 3-0-6
Credit cannot also be received for15.724
______
Provides a rigorous introduction to the fundamentals of modern financial analysis and applications to business challenges in capital budgeting, project evaluation, corporate investment and financing decisions, and basic security analysis and investment management. Focuses on five key sections: an introduction to the financial system, the unifying principles of modern finance, and fundamental present-value relations; valuation models for both stocks and bonds and capital budgeting; methods for incorporating uncertainty into valuation models; valuation of derivative securities; and applications to corporate financial decisions. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
Staff
No textbook information available

15.415 Finance Theory
______

Graduate (Summer)
Prereq: None
Units: 6-0-9
______
Core theory of capital markets and corporate finance. Topics include functions and operations of capital markets, analysis of consumption-investment decisions of investors, valuation theory, financial securities, risk analysis, portfolio theory, pricing models of risky assets, theory of efficient markets, as well as investment, financing and risk management decisions of firms. Provides a theoretical foundation of finance and its applications. Restricted to students in the Master of Finance Program.
L. Kogan, J. Wang
Textbooks (Summer 2016)

15.416[J] Introduction to Financial Economics
______

Graduate (Fall)
(Same subject as14.416[J])
Prereq: 14.121, 14.122
Units: 4-0-8
Lecture: MW2.30-4 (E51-063) Recitation: F11 (E62-221)
______
Foundations of modern financial economics; individuals' consumption and portfolio decisions under uncertainty; valuation of financial securities. Topics include expected utility theory; stochastic dominance; mutual fund separation; portfolio frontiers; capital asset pricing model; arbitrage pricing theory; Arrow-Debreu economies; consumption and portfolio decisions; consumption beta models; spanning; options; market imperfections; no-trade theorems; rational expectations; financial signaling. Primarily for doctoral students in accounting, economics, and finance.
S. Ross
Textbooks (Fall 2016)

15.417 Laboratory in Investments
______

Undergrad (Spring) Institute Lab
Prereq: None
Units: 4-2-9
Credit cannot also be received for15.401
______
Students work in teams to construct a portfolio of assets (equities, bonds, or some combination). Presents elements of portfolio construction, risk assessment, and metrics to gauge the effectiveness of trading strategies. Emphasizes the use of research databases to test hypotheses regarding the predictability of asset returns, as well as the impact of market microstructure and behavioral effects. Instruction and practice in oral and written communication provided.
G. Rao

15.418 Laboratory in Corporate Finance
______

Undergrad (Fall, Spring) Institute Lab
Prereq: 15.417
Units: 4-2-9
Credit cannot also be received for15.402
Lecture: MW10-11.30 (E62-276) or MW1-2.30 (E62-276) Lab: F2.30-4 (E52-164) +final
______
Covers capital budgeting, investment decisions and valuation; working capital management, security issues; dividend policy; optimal capital structure; and real options analysis. Laboratory involves projects of an applied nature in which students either conduct an event study and analyze its impact on firm capital market value, or conduct a merger model between two firms of the student's choosing. Emphasizes use of research databases to test hypotheses. Instruction and practice in communication includes report writing, team projects, and oral and visual presentation. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
S. Myers
Textbooks (Fall 2016)

15.426[J] Real Estate Finance and Investment
______

Graduate (Fall)
(Same subject as11.431[J])
Prereq: Permission of instructor
Units: 4-0-8
Lecture: MW4-5.30 (9-354) Recitation: M EVE (5.30-7 PM) (9-354)
______
Concepts and techniques for analyzing financial decisions in commercial property development and investment. Topics include property income streams, urban economics, discounted cash flow, equity valuation, leverage and income tax considerations, development projects, and joint ventures.
D. Geltner
Textbooks (Fall 2016)

15.427[J] Real Estate Capital Markets
______

Graduate (Spring); first half of term
(Same subject as11.432[J])
Prereq: 11.431; 15.402 or 15.414
Units: 2-0-4
______
Introduces real estate capital markets for institutional investors. Topics include real estate investment trusts (REIT), commercial mortgage-backed securities (CMBS), and private equity. Concepts and techniques for investment analysis include portfolio theory and equilibrium asset pricing. Additional topics may include price indexing and derivatives.
D. Geltner

15.428[J] Tools for Analysis: Design for Real Estate and Infrastructure Development
______

Graduate (Spring); second half of term
(Same subject as11.434[J],IDS.671[J])
Prereq: None
Units: 2-0-4
______
Introduction to analytical tools to support design and decision-making in real estate, infrastructure development, and investment. Particular focus on identifying and valuing sources of flexibility using "real options," Monte-Carlo simulation, and other techniques from the field of engineering systems. Integrates economic and engineering perspectives, and is suitable for students with various backgrounds. Provides useful preparation for thesis work in the area.
D. Geltner, R. de Neufville

15.429[J] Securitization of Mortgages and Other Assets
______

Graduate (Spring)
(Same subject as11.353[J])
Prereq: 15.426, 15.401, or permission of instructor
Units: 3-0-6
______
Investigates the economics and finance of securitization, a practice that allows illiquid assets to be transformed into more liquid securities. Considers the basic mechanics of structuring deals for various asset-backed securities. Investigates the pricing of pooled assets, using Monte Carlo and other option pricing techniques, as well as various trading strategies used in these markets.
W. Torous

15.431 Entrepreneurial Finance and Venture Capital
______

Graduate (Fall)
Prereq: 15.402, 15.414, or 15.415
Units: 3-0-6
Credit cannot also be received for15.4311
Lecture: TR1-2.30 (E51-395) or TR2.30-4 (E51-395) +final
______
Examines the elements of entrepreneurial finance, focusing on technology-based start-up ventures, and the early stages of company development. Addresses key questions which challenge all entrepreneurs: how much money can and should be raised; when should it be raised and from whom; what is a reasonable valuation of a company; and how funding, employment contracts and exit decisions should be structured. Aims to prepare students for these decisions, both as entrepreneurs and venture capitalists. In-depth analysis of the structure of the private equity industry. Meets with 15.4311 when offered concurrently. Expectations and evaluation criteria for graduate students will differ from those of undergraduates; consult syllabus or instructor for specific details.
Staff
No required or recommended textbooks

15.4311 Entrepreneurial Finance and Venture Capital
______

Undergrad (Spring)
Prereq: 15.418
Units: 3-0-6
Credit cannot also be received for15.431
______
Examines the elements of entrepreneurial finance, focusing on technology-based start-up ventures, and the early stages of company development. Addresses key questions which challenge all entrepreneurs: how much money can and should be raised; when should it be raised and from whom; what is a reasonable valuation of a company; and how funding, employment contracts and exit decisions should be structured. Aims to prepare students for these decisions, both as entrepreneurs and venture capitalists. In-depth analysis of the structure of the private equity industry. Meets with 15.431 when offered concurrently. Expectations and evaluation criteria for graduate students will differ from those of undergraduates; consult syllabus or instructor for specific details.
A. Schoar

15.433 Financial Markets
______

Graduate (Fall)
(Subject meets with15.4331)
Prereq: 15.401, 15.414, or 15.415
Units: 3-0-6
Lecture: TR8.30-10 (E52-164) or TR10-11.30 (E52-164) +final
______
Financial theory and empirical evidence for making investment decisions. Topics include portfolio theory; equilibrium models of security prices, including the capital asset pricing model and the arbitrage pricing theory; the empirical behavior of security prices; market efficiency; performance evaluation; and behavioral finance. Meets with 15.4331 when offered concurrently. Students taking graduate version complete additional assignments. Preference to Course 15 students.
J. Pan
Textbooks (Fall 2016)

15.4331 Financial Markets
______

Undergrad (Fall)
(Subject meets with15.433)
Prereq: 15.411
Units: 3-0-6
Lecture: TR8.30-10 (E52-164) or TR10-11.30 (E52-164) +final
______
Covers financial theory and empirical evidence for making investment decisions. Topics include portfolio theory; equilibrium models of security prices, including the capital asset pricing model and the arbitrage pricing theory; empirical behavior of security prices; market efficiency; performance evaluation; and behavioral finance. Meets with 15.433 when offered concurrently. Students taking graduate version complete additional assignments. Preference to Course 15 students.
J. Pan
Textbooks (Fall 2016)

15.434 Advanced Corporate Finance
______

Graduate (Fall, Spring)
(Subject meets with15.4341)
Prereq: 15.402, 15.414, or 15.415
Units: 3-0-6
Lecture: MW10-11.30 (E62-233) or MW1-2.30 (E52-164)
______
Covers advanced topics in corporate finance, including complex valuations, static and dynamic capital structure, risk management, and real options. Also considers security design, restructuring, bankruptcy, corporate control and governance, and international finance issues. Students taking the graduate version complete additional assignments.
N. Bergman
Textbooks (Fall 2016)

15.4341 Advanced Corporate Finance
______

Undergrad (Fall, Spring)
(Subject meets with15.434)
Prereq: 15.418
Units: 3-0-6
Lecture: MW10-11.30 (E62-233) or MW1-2.30 (E52-164)
______
Covers advanced topics in corporate finance, including complex valuations, static and dynamic capital structure, risk management, and real options. Also considers security design, restructuring, bankruptcy, corporate control and governance, and international finance issues. Students taking graduate version complete additional assignments.
N. Bergman
Textbooks (Fall 2016)

15.437 Options and Futures Markets
______

Graduate (Fall)
Prereq: 15.401, 15.414, or 15.415
Units: 3-0-6
Credit cannot also be received for15.4371
Lecture: MW1-2.30 (E51-376) or MW2.30-4 (E51-376)
______
Examines the economic role of options and futures markets. Topics include determinants of forward and futures prices, hedging and synthetic asset creation with futures, uses of options in investment strategies, relation between puts and calls, option valuation using binomial trees and Monte Carlo simulation, implied binomial trees, advanced hedging techniques, exotic options, and applications to corporate securities and other financial instruments. Meets with 15.4371 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. C. Cox
Textbooks (Fall 2016)

15.4371 Options and Futures Markets
______

Undergrad (Fall)
Prereq: 15.417
Units: 3-0-6
Credit cannot also be received for15.437
Lecture: MW1-2.30 (E51-376) or MW2.30-4 (E51-376)
______
Examines the economic role of options and futures markets. Topics include determinants of forward and futures prices, hedging and synthetic asset creation with futures, uses of options in investment strategies, relation between puts and calls, option valuation using binomial trees and Monte Carlo simulation, implied binomial trees, advanced hedging techniques, exotic options, and applications to corporate securities and other financial instruments. Meets with 15.437 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. C. Cox
Textbooks (Fall 2016)

15.438 Fixed Income Securities and Derivatives
______

Graduate (Spring)
Prereq: 15.401, 15.414, or 15.415
Units: 3-0-6
______
Designed for students seeking to develop a sophisticated understanding of fixed income valuation and hedging methods, and to gain familiarity with the major markets and instruments. Emphasizes tools for quantifying, hedging, and speculating on risk. Topics include duration; convexity; modern approaches to modeling the yield curve; interest rate forwards, futures, swaps and options; credit risk and credit derivatives; mortgages; and securitization. 15.437 strongly recommended.
D. Lucas

15.439 Investment Management
______

Graduate (Spring)
Prereq: 15.401, 15.414, or 15.415
Units: 3-0-6
______
Studies financial markets, principally equity markets, from an investment decision-making perspective. Develops a set of conceptual frameworks and tools, and applies them to particular investments and investment strategies chosen from a broad array of companies, securities, and institutional contexts. Focuses strongly on case studies; students are expected to prepare each case before class and participate extensively in discussions.
R. Cohen

15.440[J] Advanced Financial Economics I
______

Graduate (Spring)
(Same subject as14.440[J])
Prereq: 15.416
Units: 5-0-7
______
Covers advanced topics in the theory of financial markets with a focus on continuous time models. Topics include multiperiod securities markets and martingales; pricing of contingent securities such as options; optimal consumption and portfolio problems of an individual; dynamic equilibrium theory and the intertemporal capital asset pricing model; term structure of interest rates; and equilibrium with asymmetric information, transaction costs, and borrowing constraints. Primarily for doctoral students in finance, economics, and accounting.
H. Chen, L. Kogan

15.441[J] Advanced Financial Economics II
______

Graduate (Spring)
(Same subject as14.441[J])
Prereq: 14.121, 14.122, or 15.416J
Units: 3-0-9
______
Surveys selected topics in current advanced research in corporate finance. Theoretical and empirical analyses of corporate financing and investment decisions. Some background in information economics and game theory is useful. Primarily for doctoral students in accounting, economics, and finance.
Staff

15.442[J] Advanced Financial Economics III
______

Graduate (Fall)
(Same subject as14.442[J])
Prereq: 14.382, 15.416J, or permission of instructor
Units: 3-0-9
Lecture: TR2.30-4 (E62-687) Recitation: M EVE (6-7.30 PM) (E51-372)
______
Recent empirical methods in finance, including: the estimation and testing of market efficiency; the random walk hypothesis; the CAPM/APT; various term structure models; option pricing theories; and market microstructures; performance evaluation; bond rating and default analysis; event study methodology; continuous-time econometrics; and general time series methods. An empirical term project is required. Some econometric background and rudimentary computer programming skills are assumed. Primarily for doctoral students in finance, accounting, and economics.
Staff
Textbooks (Fall 2016)

15.444 International Corporate Finance
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 15.402, 15.414, or 15.415
Units: 3-0-6
______
Addresses issues relating to valuation, risk management, financing and contractual design for firms operating in international markets, providing exposure to emerging markets. Students analyze how risk and cash flows should be evaluated in environments with varying levels of risk, such as currency fluctuation, sovereign default, weak property rights, etc. Discusses how certain types of risk can be eliminated or managed through the appropriate design of financial contracts, and how institutional differences across countries shape the structure and efficacy of private equity contracts. Other topics include firm policy and international tax regimes, microfinance, and valuing social return. Concludes with a discussion on the impact of global financial crises on firm financial policy.
Staff

15.445 Mergers and Acquisitions: The Market for Corporate Control
______

Graduate (Spring); partial term
Prereq: 15.515 or 15.516; 15.414, 15.415, orCoreq: 15.402
Units: 2-0-4
______
Examines a corporation's decision to acquire another firm or the decision to oppose being acquired. Explores three aspects of the merger and acquisition process: the strategic decision to acquire, the valuation decision of how much to pay, and the financing decision on how to fund the acquisition. Sessions alternate between discussions of academic readings and applied cases.
N. Gregory

15.447 International Capital Markets
______

Graduate (Spring)
Prereq: 15.401, 15.414, or 15.415
Units: 3-0-6
______
Covers globalization of capital markets and implications for financial management of domestic businesses, multinationals, and portfolios. Topics include currency markets, measuring and managing exchange rate exposure, exchange rate determination and forecasting, international financial instruments and institutions, international trading strategies and valuation, and global financial crises.
J. Parker

15.448-15.449 Seminar in Finance
______

Graduate (Fall) Can be repeated for credit
Prereq: 15.402 or 15.414
Units arranged
15.448: TBA.
15.449: TBA.
______
Group study of current topics related to finance.
J. C. Cox
15.448: No textbook information available
15.449: No textbook information available

15.450 Analytics of Finance
______

Graduate (Spring)
Prereq: 15.401, 15.414, or 15.415
Units: 5-0-7
______
Provides a rigorous foundation for the main analytical techniques and quantitative methods necessary to succeed in the financial services industry. Topics include discrete and continuous asset pricing models, financial econometrics, machine learning methods, and dynamic optimization. Examples of applications include portfolio management, risk management, derivative pricing, and algorithmic trading.
H. Chen

15.451 Proseminar in Capital Markets/Investment Management
______

Graduate (Fall)
Prereq: 15.401, 15.414, or 15.415
Units: 2-0-4
Lecture: R EVE (4-6 PM) (E52-164)
______
Provides a unique opportunity to tackle original research problems in capital market analysis and investment management that have been posed by leading experts from the financial community. Students are assigned to teams, and each team is assigned one such problem. Teams present their solutions at a seminar which is attended by representatives of the sponsoring organization and open to the entire MIT community. Not open to students from other institutions.
H. Chen, M. Kritzman
No required or recommended textbooks

15.452 Proseminar in Corporate Finance/Investment Banking
______

Graduate (Fall)
Prereq: 15.402, 15.414, or 15.415
Units: 3-0-3
Lecture: T4-5.30 (E62-262) or T EVE (6-7.30 PM) (E62-262)
______
Bridges the gap between finance theory and finance practice, and introduces students to the broader financial community. Students participate in a series of proseminars with industry guest speakers. Each guest, in collaboration with finance faculty, provides a problem and materials to a team of students. Each team then prepares a report and presents their analysis to the guest speaker and other students for evaluation and feedback. Not open to students from other institutions.
J. Parsons
No required or recommended textbooks

15.460 Financial Engineering
______

Graduate (Fall)
Prereq: 15.401, 15.414, or 15.415
Units: 4-0-5
Lecture: MW2.30-4 (E62-223) +final
______
Provides an introduction to financial engineering, covering topics such as asset pricing theory and applications, optimization, market equilibrium, market frictions, risk management, and advanced topics. Assumes solid undergraduate-level background in calculus, probability, statistics, and programming and includes a substantial coding component. Materials and review sessions use R. Students are encouraged but not required to use R for assignments and projects.
L. Kogan, A. Lo, J. Wang
No required or recommended textbooks

15.466 Functional and Strategic Finance
______

Graduate (Spring)
Prereq: 15.433 or 15.437
Units: 3-0-6
______
Organized around applying finance science and financial engineering in the design and management of global financial institutions, markets, and the financial system - the approach used to understand the dynamics of institutional change and the design of financial products and services. Examines the needs of government as user, producer and overseer of the financial system, including the issues surrounding measuring and managing risks in financial crises. Develops the necessary tools of derivative pricing and risk measurement, portfolio analysis and risk accounting, and performance measurement to analyze and implement concepts and new product ideas. Applies these tools to analyze aspects of the financial crisis of 2007-2009. Preference to MBA and MFin students.
R. Merton

15.467 Asset Management, Lifecycle Investing, and Retirement Finance
______

Graduate (Spring)
Prereq: 15.433
Units: 3-0-6
______
Organized around applying finance science and financial engineering in three related financial-service activities: asset management, lifecycle investing, and retirement finance. Develops the necessary tools of derivative pricing and risk measurement, portfolio analysis and risk accounting, and performance measurement to analyze and implement concepts and new product ideas. Students should be familiar with basic portfolio-selection theory, CAPM, options, futures, swaps and other derivative securities. Preference to MBA and MFin students.
R. Merton

15.481[J] Financial Market Dynamics and Human Behavior
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as6.935[J])
Prereq: 15.401, 15.414, or 15.415
Units: 4-0-5
______
Develops a new perspective on the dynamics of financial markets and the roles that human behavior and the business environment play in determining the evolution of behavior and institutions. Draws on a variety of disciplines to develop a more complete understanding of human behavior in the specific context of markets and other economic institutions. Incorporates practical applications from financial markets, the hedge fund industry, private equity, government regulation, and political economy. Students use ideas from this new perspective to formulate several new hypotheses regarding recent challenges to traditional economic thinking.
A. Lo

15.490 Practice of Finance: Private Equity and Hedge Funds
______

Graduate (Spring); second half of term
Prereq: 15.402, 15.414, or 15.415
Units: 2-0-1
______
Introduction to the field of alternative investments - principally private equity and hedge funds - within the context of the larger investment domain. Covers the structure and operation of alternative funds, valuation, and topics such as deal sourcing, exits, value added, and alpha strategies. Discusses the evolution of the field as well as what the future may bring. Summarizes subfields such as venture capital, leveraged buyouts, distressed investing, and the spectrum of hedge funds. Addresses investor perspectives, portfolio construction and risk management with alternatives. Encourages active student participation, and includes a project and reading list.
P. Cooper

15.491 Practice of Finance: Advanced Corporate Risk Management
______

Graduate (Spring); second half of term
Prereq: 15.402, 15.414, or 15.415
Units: 2-0-4
______
Focuses on how corporations make use of the insights and tools of risk management. Taught from the perspective of potential end-users of derivatives (not the dealer), such as manufacturing corporations, utilities, and software firms. Topics include how companies manage risk, instruments for hedging, liability management and organization, and governance and control. 15.437 recommended.
J. Parsons

15.493 Practice of Finance: Perspectives on Investment Management
______

Graduate (Fall, Spring); second half of term
Prereq: 15.402, 15.414, or 15.415
Units: 3-0-3 [P/D/F]
Begins Oct 31. Lecture: W EVE (4-7 PM) (E51-335)
______
Provides an overview of the investment management industry and an introduction to business fundamentals and valuation. Students read company analyst reports, write papers analyzing various companies, and complete an in-depth company analysis as a final paper. Includes presentations by outside speakers in the investment management industry. Class attendance is mandatory.
J. Shames
Textbooks (Fall 2016)

15.496 Practice of Finance: Data Technologies for Quantitative Finance
______

Graduate (Fall)
Prereq: 15.401, 15.414, or 15.415
Units: 4-0-5
Lecture: T EVE (4-6 PM) (E62-250) Recitation: F9-10.30 (E51-057)
______
Introduces financial market data architecture and design, with applications to asset pricing, quantitative investment strategies, portfolio management, risk management, and high-frequency trading. Studies how data relationships are structured and how to use modern tools and technologies to manipulate, manage, and analyze financial data sets. Uses real-world data, applications, and cases to illustrate principles and provide practical experience.
P. Mende
No required or recommended textbooks

Accounting

15.501 Corporate Financial Accounting
______

Undergrad (Fall, Spring)
(Subject meets with15.516)
Prereq: None
Units: 3-0-9
URL: http://mitsloan.mit.edu/students/academiclife/XReg/15.501.pdf
Lecture: TR1-2.30 (4-237) or TR2.30-4 (4-237) +final
______
Preparation and analysis of financial statements. Focuses on why financial statements take the form they do, and how they can be used in evaluating corporate performance and solvency and in valuation of corporate securities. Introduces concepts from finance and economics (e.g., cash flow discounting and valuation) and explains their relation to, and use in, accounting. Students taking the graduate version complete additional assignments. Permission of Sloan Educational Services required for all cross-registrants.
J. Granja
Textbooks (Summer 2016); Textbooks (Fall 2016)

15.511 Financial Accounting
______

Graduate (Summer)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.720
______
Introduces concepts of corporate financial accounting and reporting of information widely used in making investment decisions, corporate and managerial performance assessment, and valuation of firms. Students perform economics-based analysis of accounting information from the viewpoint of the user (especially senior managers) rather than the preparer (the accountant). Restricted to Sloan Fellows in Innovation and Global Leadership.
J. Weber
No textbook information available

15.514 Financial and Managerial Accounting
______

Graduate (Summer)
Prereq: None
Units: 3-0-9
______
Intensive introduction to the preparation and interpretation of financial information for investors (external users) and managers (internal users) and to the use of financial instruments to support system and project creation. Adopts a decision-maker perspective on accounting and finance. Restricted to System Design and Management students.
S. Keating

15.515 Financial Accounting
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 4-0-5
Lecture: TR8.30-10 (E62-276, E51-335, E62-223) or TR10-11.30 (E62-276, E51-335, E62-223) Recitation: R1 (E62-233, E51-085) or R3 (E51-376) or R4 (E51-149, E51-085) or R3 (E51-149) +final
______
An intensive introduction to the preparation and interpretation of financial information. Adopts a decision-maker perspective of accounting by emphasizing the relation between accounting data and the underlying economic events generating them. Class sessions are a mixture of lecture and case discussion. Assignments include textbook problems, analysis of financial statements, and cases. Restricted to first-year Sloan master's students.
J. Core, R. Verdi
Textbooks (Fall 2016)

15.516 Corporate Financial Accounting
______

Graduate (Fall, Spring, Summer)
(Subject meets with15.501)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://mitsloan.mit.edu/students/academiclife/XReg/15.501.pdf
Lecture: TR1-2.30 (4-237) or TR2.30-4 (4-237) +final
______
See description under subject 15.501. If subject is oversubscribed, priority is given to Course 15 students.
N. Shroff
Textbooks (Summer 2016); Textbooks (Fall 2016)

15.518 Taxes and Business Strategy
______

Graduate (Spring)
Prereq: 15.501, 15.511, 15.515, or 15.516
Units: 3-0-6
Credit cannot also be received for15.5181
______
Provides conceptual framework for thinking about taxation. Topics include taxation of various investments and types of compensation; retirement planning; considerations of choosing an organizational form when starting a business; various methods of mergering, acquiring, and divesting business entities; international tax planning rules and strategies; and high wealth planning and estate tax. Applies current debates on various tax policy options to class discussions. Intended for investment bankers and consultants who need to understand how taxes affect the structure of deals, managers and analysts who need to understand how firms strategically respond to taxes, and entrepreneurs who want to structure their businesses and finances in a tax-advantaged manner. Meets with 15.5181 when offered concurrently. Expectations and evaluation criteria for graduate students will differ from those of undergraduates; consult syllabus or instructor for specific details.
M. Hanlon

15.5181 Taxes and Business Strategy
______

Undergrad (Spring)
Prereq: 15.501
Units: 3-0-6
Credit cannot also be received for15.518
______
Provides conceptual framework for thinking about taxation. Topics include taxation of various investments and types of compensation; retirement planning; considerations of choosing an organizational form when starting a business; various methods of mergering, acquiring, and divesting business entities; international tax planning rules and strategies; and high wealth planning and estate tax. Applies current debates on various tax policy options to class discussions. Meets with 15.518 when offered concurrently. Expectations and evaluation criteria for graduate students will differ from those of undergraduates; consult syllabus or instructor for specific details.
M. Hanlon

15.521 Management Accounting and Control
______

Graduate (Spring)
Prereq: 15.501, 15.511, 15.515, or 15.516
Units: 3-0-6
______
Introduces participants to the language and methodologies of internal accounting practices. Topics include cost allocations, absorption costing, standard costing, transfer pricing, and performance measurement and evaluation. Major focus is on identifying which information is useful and which is useless and potentially misleading.
S. Keating

15.522 Security Design and Corporate Financing
______

Graduate (Spring)
Prereq: 15.401; 15.402 or 15.414; 15.433 or 15.434
Units: 3-0-6
______
Examines how corporations choose securities and markets to finance themselves. These are decisions which the firm must make after it has determined its financial policies including capital structure and dividend policy. Subject discusses recent trends in corporate financing including globalization, secularization, and transformation. Explores new securities and institutional factors, particularly tax and accounting factors that affect their design.
P. Asquith

15.535 Business Analysis Using Financial Statements
______

Graduate (Fall, Spring)
Prereq: 15.501, 15.511, 15.515, or 15.516; 15.401, 15.414, or 15.415
Units: 3-0-6
Lecture: MW1-2.30 (E51-335) or MW2.30-4 (E51-335)
______
Primary learning objective is the strategic, financial, and accounting analysis of a company's profitability and riskiness by means of financial statement data. A second, and related, learning objective is the valuation of a company using financial statement data. Concepts are applied to a number of decision making contexts, including securities analysis, credit analysis, merger analysis, and company performance assessment.
C. Noe
Textbooks (Fall 2016)

15.539 Doctoral Seminar in Accounting
______

Graduate (Fall) Can be repeated for credit
Prereq: 15.515
Units arranged
TBA.
______
Designed primarily for doctoral students in accounting and related fields. The reading list consists of accounting research papers. Objective is to introduce research topics, methodologies, and developments in accounting, and train students to do independent research.
J. Weber
No textbook information available

Information Technologies

15.561 Information Technology Essentials
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: None
Units: 3-0-6
URL: http://web.mit.edu/15.561/www/
______
Examines technology concepts and trends underlying current and future uses of information technology (IT) in business. Emphasis on networks and distributed computing, including the web. Other topics include hardware and operating systems, software development tools and processes, relational databases, security and cryptography, enterprise applications, and electronic commerce. Exposure to web, database, and graphical user interface (GUI) tools. Primarily for Sloan master's students with limited IT background.
T. W. Malone

15.564 IT Essentials II: Advanced Technologies for Digital Business in the Knowledge Economy
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
______
Technologies and concepts for next generation knowledge management and web e-business, including semantic web and web services. Business applications for use in the next two to seven years, including: e-commerce, marketing, finance, trust/security, health/biomedical, mobile. Strategic impacts and entrepreneurial opportunities. Core skills for identifying and evaluating technologies and their business potential, and for managing innovative IT-dependent projects. Overall emphasis on business process automation and e-services.
S. Madnick

15.565[J] Digital Evolution: Managing Web 3.0
______

Graduate (Fall)
(Same subject asIDS.345[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://mitsloan.mit.edu/course/15565.html
Lecture: TR2.30-4 (E62-250)
______
Examines the evolution from Web 2.0, with its emphasis on interactivity through online collaboration and sharing among users (primarily through social networking sites, wikis and communication tools), to Web 3.0, which focuses on high proactivity, transforming the Web into a database, and the leveraging of artificial intelligence technologies, such as the Semantic Web. Introduces Management 3.0 and the range of new Web technologies, applications, and business opportunities and challenges that it supports. Addresses topics such as big data, cloud computing, and cybersecurity. Includes case studies, industry and academic speakers, discussion of basic principles, and a team project.
S. Madnick
No textbook information available

15.567 The Economics of Information: Strategy, Structure and Pricing
______

Graduate (Fall); first half of term
Prereq: Permission of instructor
Units: 3-0-3
Ends Oct 21. Lecture: TR1-2.30 (E62-262)
______
Analysis of the underlying economics of information with management implications. Studies effects of digitization and technology on business strategy and organizational structure. Examines pricing, bundling, and versioning of digital goods, including music, video, software, and communication services. Considers the managerial implications of data-driven decision-making, search, targeted advertising, personalization, privacy, network externalities, open source, and alliances. Readings on fundamental economic principles inform provide context for industry speakers and case discussions.
E. Brynjolfsson
No textbook information available

15.569 Leadership Lab: Leading Sustainable Systems
______

Graduate (Fall, IAP)
Prereq: Permission of instructor
Units: 6-0-9
Extra classes: 9/21 and 9/22. Lecture: M2.30-5.30 (E62-233) Recitation: M EVE (5.30-8.30 PM) (E62-233)
______
Addresses key sustainability challenges faced by business and society. Explores alternative ways to view organizations that draw attention to cross-boundary interdependencies and help leaders at all levels develop their capacity to collaborate for systemic change. Develops skills to help students surface and reflect on mental models and practices that keep organizations stuck in unproductive system dynamics. Weaves together theory, experiential practices, guest speakers, and action learning projects that enable teams of students to work with organizations on systemic change initiatives.
P. Senge, W. Orlikowski
Textbooks (Fall 2016)

15.570 Digital Marketing and Social Media Analytics
______

Graduate (Fall); second half of term
Prereq: None
Units: 3-0-3
Begins Oct 31. Lecture: TR1-2.30 (E62-262) or TR2.30-4 (E62-262)
______
Provides a detailed, applied perspective on the theory and practice of digital marketing and social media analytics in the age of big data. Covers concepts such as the difference between earned and paid media, predictive modeling for ad targeting and customer relationship management, measuring and managing product virality, viral product design, native advertising, and engaging the multichannel experience. Stresses the theory and practice of randomized experimentation, AB testing and the importance of causal inference for marketing strategy. Combines lectures, case studies, and guest speakers with relevant industry experience that speak directly to the topics at hand.
S. Aral
No textbook information available

15.571 Enterprise Transformations in the Digital Economy
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
______
Designed to help students understand how the digital economy forces companies to rethink their business strategies--and architect their processes, products, and information. Explores how firms use technology to simplify unnecessary complexity while capitalizing on the value-adding complexity inherent to more global, more integrated, more connected enterprises. Includes case studies about large enterprises using IT to transform how they do business, with guest executives from those enterprises responding to student discussions. Student teams work on consulting projects for major corporaitons.
J. W. Ross

15.572 Analytics Lab: Action Learning Seminar on Analytics, Machine Learning, and the Digital Economy
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-0-7
Lecture: R4-5.30 (E62-262)
______
Student teams design and deliver a project based on the use of analytics, machine learning, large data sets, or other digital innovations to create or transform a business or other organization. Teams may be paired up with an organization or propose their own ideas and sites for the project. Culminates with presentation of results to an audience that includes IT experts, entrepreneurs, and executives.
S. Aral, E. Brynjolfsson
No textbook information available

15.575 Economics of Information and Technology in Markets and Organizations
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
______
Builds upon relevant economic theories and methodologies to analyze the changes in organizations and markets enabled by IT, especially the internet. Typical perspectives examined include industrial organization and competitive behavior, price theory, information economics, intangible asset valuation, consumer behavior, search and choice, auctions and mechanism design, transactions cost economics and incomplete contracts theory, and design of empirical studies. Extensive reading and discussion of research literature aimed at exploring the application of these theories to business issues and challenges raised by the internet and related technologies. Primarily for doctoral students.
E. Brynjolfsson

15.576 Research Seminar in Information Technology and Organizations: Social Perspectives
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: R1-4 (E62-587)
______
Examines the assumptions, concepts, theories, and methodologies that inform research into the social aspects of technology. Extensive reading and discussion of research literature aimed at exploring the multiple social phenomena surrounding the development, implementation, use and implications of information technology in organizations. Primarily for doctoral students.
W. J. Orlikowski
No textbook information available

15.579-15.580 Seminar in Information Technology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
15.579: URL: http://web.mit.edu/15.579/www/15.579.html
15.579: Lecture: W1-4 (E62-221)
15.580: TBA.
______
Group study of current topics related to information technology.
S. E. Madnick, T. W. Malone, W. Orlikowski
15.579: No textbook information available
15.580: No textbook information available

15.599 Workshop in Digitization
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
TBA.
______
Presentations by faculty, doctoral students, and guest speakers of ongoing research relating to current issues in digitization, technology and the changing economics of work, as well as discussions of key research papers in the field. Specific topics determined by the interest of participants and by new and important directions in digitization, information technology and information economics. Background readings, regular assignments and active participation by students expected. Preference to doctoral students.
E. Brynjolfsson
No textbook information available

Law

15.615 Essential Law for Business
______

Graduate (Fall, Spring)
Prereq: None
Units: 3-0-6
Lecture: MW8.30-10 (E51-149)
______
Provides a broad-gauged introduction to business law, including how law shapes business opportunities and risks. Imparts skills necessary for dealing effectively with law-sensitive aspects of company restructurings and mergers and acquisitions; contracts, complex deals, and financial instruments and facilities; innovation in business models, products, and services; and encounters with regulators. Also discusses individual and organizational accountability to private parties and public authorities, and key legal issues in career transitions.
J. Akula
Textbooks (Fall 2016)

15.616 Basic Business Law, Tilted Towards Key Emerging Issues
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: None
Units: 3-0-6
______
Broad-gauged introduction to business law designed to prepare managers to exercise judgment and leadership when confronting key law-sensitive issues of importance to their organizations and their own careers. Topics include contracts, liability, employment, changing jobs, intellectual property, business disputes, bankruptcy and reorganization, acquisitions, regulatory compliance, and corporate crime. The distinctive feature of 15.616 is an additional focus on newly-emerging, law-sensitive issues of key significance to business. Those topics vary from year to year; some recent examples include doing business in the BRIC nations, and the legal framework of social media.
J. Akula

15.617 Deals, Finance, and the Law
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.6171
______
Addresses law-sensitive issues arising in the overlapping contexts of complex deals and financial services and products. Covers financial services regulation, employment and job changes, and civil and criminal accountability. Develops managerial skills for handling law-sensitive situations at individual and organizational levels. Meets with 15.6171 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. Akula

15.6171 Deals, Finance, and the Law
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.617
______
Addresses law-sensitive issues arising in the overlapping contexts of complex deals and financial services and products. Covers financial services regulation, employment and job changes, and civil and criminal accountability. Develops managerial skills for handling law-sensitive situations at individual and organizational levels. Meets with 15.617 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. Akula

15.618 Entrepreneurship and Innovation: Legal Tools and Frameworks
______

Graduate (Fall, Spring)
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: T EVE (4-6 PM) (E51-149)
______
Focuses on key law-sensitive issues related to launching and growing a startup, including assembling a team; organizing a business entity; ownership and compensation; early financing; managing contracts, employees, and common early business risks; business distress, winding down, and soft landings; and selling a company. Special attention to innovation-driven ventures built around new technologies or business models. Includes in-depth analysis of the legal framework of cutting-edge technologies and rights in intellectual property. Designed to serve both those with a business background and those engaged in research with commercial potential.
J. Akula
Textbooks (Fall 2016)

15.647-15.649 Seminar in Law
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
15.647: TBA.
15.648: TBA.
15.649: TBA.
______
Group study of current topics related to law.
J. L. Akula
15.647: No textbook information available
15.648: No textbook information available
15.649: No textbook information available

15.657[J] Technology, Globalization, and Sustainable Development
______

Graduate (Fall)
(Same subject as1.813[J],11.466[J],IDS.437[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: W EVE (4-6.30 PM) (E51-376)
______
Investigates sustainable development, taking a broad view to include not only a healthy economic base, but also a sound environment, stable employment, adequate purchasing power, distributional equity, national self-reliance, and maintenance of cultural integrity. Explores national, multinational, and international political and legal mechanisms to further sustainable development through transformation of the industrial state. Addresses the importance of technological innovation and the financial crisis of 2008.
N. Ashford
Textbooks (Fall 2016)

Industrial Relations and Human Resource Management

15.660 Strategic Human Resource Management
______

Graduate (Spring)
Prereq: 15.311
Units: 3-0-6
______
Design and execution of human resource management strategies. Two central themes: How to think systematically and strategically about aspects of managing the organization's human assets, and what really needs to be done to implement these policies and to achieve competitive advantage. Adopts the perspective of a general manager and addresses human resource topics (including reward systems, performance management, high-performance human resource systems, training and development, recruitment, retention, equal employment opportunity laws, work-force diversity, and union-management relationships) from a strategic perspective.
E. J. Castilla

15.662[J] Managing Sustainable Businesses for People and Profits
______

Graduate (Spring)
(Same subject as11.383[J])
Prereq: None
Units: 3-6-3
______
Examines opportunities and challenges involved in building and growing businesses that achieve high financial performance and provide good jobs and careers to employees. Students engage participants in the MITx online course title Shaping the Future of Work to learn about the expectations and employment experiences of workers across the world. Through readings, cases, simulations and class visits from industry leaders, explores the underlying principles and business practices that help to secure that alignment between business health and societal well-being.
T. Kochan

15.663 Environmental Law, Policy, and Economics
(New)
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Credit cannot also be received for1.801,1.811,11.021,11.630,17.393,IDS.430
Lecture: TR3.30-5 (E51-057)
______
Discusses the roles and interactions of Congress, federal agencies, state governments, and the courts in dealing with environmental problems. Topics include common law, administrative law, environmental impact assessments required by the National Environmental Policy Act. Also covers legislation and court decisions dealing with green-house gas emissions, air pollution, water pollution, the control of toxic chemicals and hazardous waste, pollution and accident prevention, community right-to-know, and environmental justice. Explores the role of science and economics in legal decisions, and economic incentives as an alternative or supplement to regulation. Analyzes pollution as an economic problem and a failure of markets. Provides an introduction to basic legal skills, including how to read and understand cases, regulation, and statutes; how to discover the current state of the law in a specific area; and how to take action toward the resolution of environmental problems.
N. Ashford, C. Caldart
No textbook information available

15.665 Power and Negotiation
______

Graduate (Fall, Spring)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.672,15.6721,15.673,15.6731,15.712
Lecture: R2.30-5.30 (E51-345) or R EVE (6-9 PM) (E51-315)
______
Provides understanding of the theory and processes of negotiation as practiced in a variety of settings. Designed for relevance to the broad spectrum of bargaining problems faced by the manager and professional. Allows students an opportunity to develop negotiation skills experientially and to understand negotiation in useful analytical frameworks. Emphasizes simulations, exercises, role playing, and cases.
J. Curhan
Textbooks (Fall 2016)

15.667 Negotiation and Conflict Management
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
______
Applies negotiation theory strategies and styles to problems managers and professionals commonly encounter in the workplace. Emphasizes sources of power in negotiation, self-assessment of personal negotiating strengths/weaknesses, and practice in negotiations via role-plays and simulations of common workplace conflicts. Covers conflict management as a direct party and as a manager helping others resolve their conflicts through mediation, investigation, arbitration, and helping the system itself to change as a result of a dispute. Special cases include bullying, harassment, dealing with difficult people, cross-cultural negotiations, and collective actions.
T. Kochan

15.668 People and Organizations
______

Undergrad (Spring)
Prereq: None
Units: 3-0-6
______
Examines the historical evolution and current human and organizational contexts in which scientists, engineers and other professionals work. Outlines major challenges facing the management profession. Uses interactive exercises, simulations and problems to develop critical skills in negotiations, teamwork, and leadership. Focuses on practical application of these skills in a professional context. Introduces concepts and tools to analyze work and leadership experiences in internships, school activities, and fieldwork. Preference to Management minors and other undergraduates not majoring in Management Science.
T. Kochan, P. Osterman

15.671 U-Lab: Transforming Self, Business and Society
______

Graduate (Fall); first half of term
Prereq: None
Units: 3-0-3 [P/D/F]
Ends Oct 21. Lecture: R EVE (5.30-9 PM) (E62-233)
______
Experiential opportunity to practice new leadership skills, such as deep listening, being present (mindfulness), and generative dialogue. In weekly coaching circles, each student has one full session to present their current leadership edge and receive feedback from peer coaches. Includes an additional action learning project.
O. Scharmer
Textbooks (Fall 2016)

15.672 Negotiation Analysis
______

Graduate (IAP)
(Subject meets with15.6721,15.673,15.6731)
Prereq: Permission of instructor
Units: 1-0-2 [P/D/F]
Credit cannot also be received for15.665,15.712
URL: http://negotiation.mit.edu/
______
Presents analytical frameworks and strategies to handle a variety of negotiation situations. Includes simulations, games, videos, lectures, discussion, and multiple opportunities to practice and hone negotiation, communication, and influence skills with extensive personalized feedback. Intended for students with a broad spectrum of backgrounds and experience levels. Six-unit version includes additional class time and outside work. Expectations and evaluation criteria differ for students taking graduate version. Limited to 80 via lottery; consult class website for information and deadlines.
J. Curhan

15.6721 Negotiation Analysis
______

Undergrad (IAP)
(Subject meets with15.672,15.673,15.6731)
Prereq: Permission of instructor
Units: 1-0-2 [P/D/F]
Credit cannot also be received for15.665,15.712
URL: http://negotiation.mit.edu/
______
Presents analytical frameworks and strategies to handle a variety of negotiation situations. Includes simulations, games, videos, lectures, discussion, and multiple opportunities to practice and hone negotiation, communication, and influence skills with extensive personalized feedback. Intended for students with a broad spectrum of backgrounds and experience levels. Six-unit version includes additional class time and outside work. Expectations and evaluation criteria differ for students taking graduate version. Limited to 80 via lottery; consult class website for information and deadlines.
J. Curhan

15.673 Negotiation Analysis
______

Graduate (IAP)
(Subject meets with15.672,15.6721,15.6731)
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Credit cannot also be received for15.665,15.712
URL: http://negotiation.mit.edu/
______
Presents analytical frameworks and strategies to handle a variety of negotiation situations. Includes simulations, games, videos, lectures, discussion, and multiple opportunities to practice and hone negotiation, communication, and influence skills with extensive personalized feedback. Intended for students with a broad spectrum of backgrounds and experience levels. Six-unit version includes additional class time and outside work. Expectations and evaluation criteria differ for students taking graduate version. Limited to 80 via lottery; consult class website for information and deadlines.
J. Curhan

15.6731 Negotiation Analysis
______

Undergrad (IAP)
(Subject meets with15.672,15.6721,15.673)
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Credit cannot also be received for15.665,15.712
URL: http://negotiation.mit.edu/
______
Presents analytical frameworks and strategies to handle a variety of negotiation situations. Includes simulations, games, videos, lectures, discussion, and multiple opportunities to practice and hone negotiation, communication, and influence skills with extensive personalized feedback. Intended for students with a broad spectrum of backgrounds and experience levels. Six-unit version includes additional class time and outside work. Expectations and evaluation criteria differ for students taking graduate version. Limited to 80 via lottery; consult class website for information and deadlines.
J. Curhan

15.676 Work, Employment, and Industrial Relations Theory
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 2-0-7
______
Historical evolution and assessment of different theories and disciplinary perspectives used in research on work, employment, and industrial relations. Introduces doctoral students to the field and explores where their research interests fit within the broader field. First part compares the normative assumptions, theories, and methodologies used by economists, historians, sociologists, psychologists, political scientists, and legal scholars from the latter nineteenth century to the present. Final portion explores strategies for advancing research on topics of current interest to participants.
T. Kochan, P. Osterman, E. Castilla, O. Sharone, M. Amengual

15.677[J] Urban Labor Markets and Employment Policy
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as11.427[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Discusses the broader trends in the labor market, how urban labor markets function, public and private training policy, other labor market programs, the link between labor market policy and economic development, and the organization of work within firms.
P. Osterman

15.678[J] Political Economy I: Theories of the State and the Economy
______

Graduate (Spring)
(Same subject as14.781[J],17.100[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Critical analysis of liberal, neoclassical, and Marxist perspectives on modern society. Alternative theories of economic growth, historical change, the state, classes, and ideology.
M. Piore, S. Berger

15.691 Research Seminar in Work, Employment and Industrial Relations
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Discusses important areas for research in work, employment and industrial relations; frameworks for research, research techniques, and methodological problems. Centered mainly on staff research and the thesis research of advanced graduate students and invited guests.
Consult T. A. Kochan
No textbook information available

15.698 Seminar in Industrial Relations and Human Resource Management
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Group study of current topics related to industrial relations and human resource management.
Consult P. Osterman
No textbook information available


left arrow|15.00-15.299|15.30-15.699|15.70-15.999 plus UROP and Thesis|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 15: Management
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Course 15: Management
Fall 2016


Executive MBA Subjects

15.700 Leadership and Integrative Management
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6 [P/D/F]
Lecture: TBA
______
Investigates the different perspectives a general manager must take, how to integrate those perspectives, and the role of leadership in setting and realizing goals. Students work intensively in teams and with multiple faculty, using a deep dive into the challenges faced by a major global firm operating in complex global markets. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.701 Innovation-Driven Entrepreneurial Advantage
______

Graduate (Spring, Summer)
Prereq: 15.714 or permission of instructor
Units: 6-0-6
______
Exposes students to the content, context, and contacts that enable entrepreneurs to design and launch successful stand-alone ventures, ventures inside established corporations, and ventures in partnership with established corporations based on new innovations. Students examine the critical entrepreneurial and innovation challenges facing entrepreneurs inside new and established firms, and develop frameworks that allow them to identify, evaluate, iterate, and integrate their ideas effectively. Case-based discussions complemented by visits to key actors in MIT labs, as well as live case studies with successful entrepreneurs. Specially designed team projects provide practical experience in entrepreneurial strategy, innovation management, and the workings of the MIT entrepreneurial ecosystem. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.702 Leading in a Global Context: Macroeconomics and Global Markets
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 6-0-6
Lecture: TBA
______
Intensive module on the global economy, combining the key perspectives of macroeconomics and global economic strategy. Focuses on the policy and economic environment of firms, as well as on the development of a more international market in products, services, and capital, and how this affects trade and industries. Presents insights into national economic strategies for development, and into the evolving rules and institutions governing the international economic order. Develops an actionable appreciation for managers of the international dimensions of economic policy and strategy in an increasingly complex world economy. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.703 Leading with Impact
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
______
Strengthens students' skills in recognizing, developing, and taking advantage of opportunities created by organizational complexity. Focuses on key topics in corporate strategy, organizational design, organizational economics, and strategic human resource management, as well as themes such as integrative management, global leadership, and innovation and entrepreneurship strategy. Emphasizes teaching through integrative, multi-perspective cases, and reflection to prepare students for the next steps in their careers as general managers. Includes two projects where students create a plan for implementing a change initiative within their organization, and develop a career plan. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.705 Organizations Lab
______

Graduate (Fall, Summer)
Prereq: Permission of instructor orCoreq: 15.716
Units: 3-0-9
Lecture: TBA
______
Preparation for an organizational change project. Emphasis on applying tools of organizational, operational, and systems analysis in order to effect change. Includes a focus on the challenges and opportunities presented by issues of leadership and organizational behavior. Each student leads a change project in his or her own organization, focusing on fixing a broken or ineffective process. Examples of possible initiatives include a strategic reorientation, organizational restructuring, introduction of a new technology, a worker participation program, etc. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.707 Global Strategy
______

Graduate (Fall, Spring)
Prereq: Permission of instructor;Coreq: 15.708
Units: 3-0-3
TBA.
______
Provides students with the evidence, concepts and models for understanding company performance in a global world and the issues facing executives in the early 21st century. Prepares students to manage effectively in todays interconnected world by understanding this changing environment, principles of global strategy, and the relation between global strategy and organization. Focuses on the specificities of strategy and organization of the multinational company. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.708 Global Organizations Lab
______

Graduate (Fall, Spring)
Prereq: Permission of instructor;Coreq: 15.707
Units: 6-0-9
Lecture: TBA
______
Helps students discover and develop new and effective ways of managing and working together across national borders; also helps accelerate development of the context awareness and integrative management skills needed to lead in a globalized world. Involves intensive team engagement with a firm where students integrate their understanding of the relevant global and national economic and institutional contexts, industry dynamics, the firm's strategic position and capabilities, and its management organization and processes to provide the management sponsor with insight and effective recommendations. Includes a week-long site visit for research. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.712 Power and Negotiation
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-3
Credit cannot also be received for15.665,15.672,15.6721,15.673,15.6731
______
Provides understanding of the theory and processes of negotiation as practiced in a variety of settings. Designed for relevance to the broad spectrum of bargaining problems faced by the manager and professional. Allows students an opportunity to develop negotiation skills experientially and to understand negotiation in useful analytical frameworks. Emphasizes simulations, exercises, role playing, and cases. Restricted to Executive MBA students.
Consult J. Lehrich

15.714 Competitive Strategy
______

Graduate (IAP, Spring, Summer)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.902
______
Introduces a variety of modern strategy frameworks and methodologies to develop the skills needed to be a successful manager. Cases and readings explore a range of strategic problems, focusing particularly on the sources of competitive advantage and the interaction between industry structure and organizational capabilities. Emphasizes the perspective of the general manager in ensuring the firm's success. Encourages awareness of both the external (market) and internal (organizational) forces that shape firm performance. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.716 Leading Organizations
______

Graduate (Summer)
Prereq: None
Units: 3-0-6 [P/D/F]
Credit cannot also be received for15.322
______
Promotes awareness of and strategies to meet the key challenges leaders face today (and tomorrow). Acquaints students with some of the psychological and sociological dynamics that regularly operate in organizational settings - the less visible but quite powerful "forces" that shape the way employees and managers respond (or don't respond) to a changing world. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.717 Organizational Processes
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Lecture: TBA
______
Designed to enhance students' ability to take effective action in complex organizational settings by providing the analytic tools needed to analyze, manage, and lead the organizations of the future. Emphasizes the importance of the organizational context in influencing which individual styles and skills are effective. Employs a wide variety of learning tools, from experiential learning to the more conventional discussion of written cases. Centers on three complementary perspectives on organizations: the strategic design, political, and cultural "lenses" on organizations. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.720 Financial Accounting
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.511
______
Examines the basic concepts of corporate financial accounting and reporting, and the role of accounting information in investment decisions, corporate and managerial performance assessment, and the valuation of firms. Develops skills for performing an economics-based analysis of accounting information from the viewpoint of the users of accounting information (especially senior managers), rather than the preparer (the accountant). Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.722 Applied Economics for Managers
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.024
Lecture: TBA
______
Develops facility with concepts, language, and analytical tools of economics. Primary focus is on microeconomics. Emphasizes integration of theory, data, and judgment in the analysis of corporate decisions and public policy, and in the assessment of changing US and international business environments. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.723 Advanced Applied Macroeconomics and International Institutions
______

Graduate (IAP, Spring)
Prereq: 15.702 or permission of instructor
Units: 3-0-3
______
Topics draw on current macroeconomic issues and events, such as modern monetary and fiscal policy; financial crisis, contagion, and currency crisis; real exchange rates, purchasing power parity, and long run sustainability; sustainable development; targeting and the new monetary policy regime; and Europe and the Euro: optimal currency areas. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.724 Financial Management
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.414
Lecture: TBA
______
Introduction to corporate finance and capital markets. Topics include project and company valuation, real options, measuring risk and return, stock pricing and the performance of trading strategies, corporate financing policy, the cost of capital, and risk management. Subject provides a broad overview of both theory and practice. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.725 Advanced Marketing Strategy
______

Graduate (IAP)
Prereq: None
Units: 1-0-2
______
Helps students consider the entire marketing mix in light of the strategy of the firm. Reviews customer-based sources of competitive advantage and discusses how to identify, measure, and leverage them. Introduces a method for comparing alternative selling formats (e.g., brick and mortar vs. electronic), aiming to find the most efficient ways to sell different products to different customers. Discusses the myriad ways in which the firm can grow its sources of competitive advantage. Provides practical experience in using tools to identify, evaluate, and develop marketing strategies; design efficient products and selling formats; and plan the use and development of the firm's portfolio of resources. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.726 Pricing
______

Graduate (IAP)
Prereq: None
Units: 1-0-2
Credit cannot also be received for15.818
______
Focuses on practical pricing tactics. Presents a framework for the steps firms should take when thinking about pricing a new product or improving the pricing performance of an old product. Tools covered include monadic pricing surveys, empirical price elasticity calculations, and conjoint. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.727 The Analytics Edge
______

Graduate (Spring)
Prereq: 15.730 or permission of instructor
Units: 3-0-3
______
Introduces modern analytics methods (data mining and optimization), starting with real-world problems where analytics have made a material difference. Modern data mining methods include clustering, classification, logistic regression, CART, random forest methods, and association rules. Modern optimization methods include robust, adaptive and dynamic optimization. Applications include health care, hospital operations, finance, energy, security, internet, and demand modeling. Uses R programming language for data mining and ROME for robust optimization. Restricted to Exeuctive MBA students.
Consult J. Hising DiFabio

15.728 Law and Strategy for the Senior Executive
______

Graduate (IAP)
Prereq: None
Units: 1-0-2
______
Designed to provide the judgment skills needed to plan, manage, and lead when confronting key law-sensitive issues in one's organization and career. Reviews how the law structures both the risks and opportunities relating to issues such as regulatory compliance, major liability exposure, and intellectual property rights. Special attention to how these play out in the context of new technologies. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.730 Data, Models, and Decisions
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.060
______
Introduces students to fundamental tools in using data to make informed management decisions. Emphasizes the executive perspective: how to leverage best-practice quantitative methods to manage and drive the business. Exercises and cases complemented by perspectives and applications in finance, operations management, healthcare, the Internet, and other functions and industries. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.732 Marketing Management
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.809,15.812
Lecture: TBA
______
Studies the application of a reasoned framework to the selection of target markets and the optimization of marketing decisions. Subject is divided into two parts: a tactical portion that reviews how firms optimize profits in their chosen markets, and a strategic portion that focuses on identifying target markets. Tactical topics include pricing, promotion, channel and product issues. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.734 Introduction to Operations Management
______

Graduate (Summer)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.761,15.7611
______
Provides concepts, techniques and tools to design, analyze and improve core strategic operational capabilities. Covers a broad range of application domains and industries, such as high-tech, financial services, insurance, automotive, health care, retail, fashion, and manufacturing. Emphasizes the effects of uncertainty in business decision making and the interplay between strategic and financial objectives and operational capabilities. Students play simulation games that demonstrate some of the central concepts. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.736 Introduction to System Dynamics
______

Graduate (Summer)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.871
______
Introduces system dynamics modeling for the analysis of business policy and strategy. Provides the skills to visualize an organization in terms of the structures and policies that create dynamics and regulate performance. Uses causal mapping, simulation models, case studies, and management flight simulators to help develop principles of policy design for successful management of complex strategies. Considers the use of systems thinking to promote effective organizational learning. Restricted to Executive MBA students.
Consult J. Lehrich
No textbook information available

15.737 Advanced System Dynamics
______

Graduate (IAP)
Prereq: 15.736 or permission of instructor
Units: 3-0-0 [P/D/F]
Credit cannot also be received for15.872
______
Workshops focus on two models: the dynamics of service quality within a firm; and industry dynamics (particularly investment cycles and bubbles), including the energy and housing markets. Emphasis on formulation, analysis, use, and decision-making. Develops modeling skills. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.738 Topics in Corporate Finance
______

Graduate (IAP)
Prereq: 15.724
Units: 1-0-2
______
Case studies and lectures introduce financial tools needed to make value-enhancing business decisions. Topics drawn from issues such as advanced valuation analysis, capital structure decisions, debt restructuring, bankruptcy, incentive problems, real options, and valuation of international projects. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.739 Discovering Your Leadership Signature
______

Graduate (IAP)
Prereq: None
Units: 1-0-2
Credit cannot also be received for15.318
______
Helps students understand their unique way of leading, i.e., leadership signature. Provides tools for students to determine what kind of leader they are and how to tell their leadership story. Examines leadership identity, drawing on theory from leadership literature, family systems, developmental psychology, personality psychology, and organizational change. Also builds on the four capabilities (4-CAP) model. Includes case studies, reflection, video analysis, and storytelling. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.740 Strategic Communication for Executives
______

Graduate (IAP)
Prereq: None
Units: 1-0-2
______
Develops communication skills crucial to successful management. Focuses on identifying a range of communication styles, and recognizing how to use them; dealing successfully with challenging or hostile audiences; understanding cross-cultural and global communication issues and differences; and leading and communicating in a crisis situation. Restricted to Executive MBA students.
Consult J. Hising DiFabio

Operations Management

15.761 Introduction to Operations Management
______

Graduate (Fall, Spring, Summer)
Prereq: 15.060, 6.041B, or permission of instructor
Units: 4-0-5
Credit cannot also be received for15.734,15.7611
Lecture: MW1-2.30 (E51-315) Recitation: F2 (E51-345)
______
Imparts concepts, techniques, and tools to design, analyze, and improve core operational capabilities and apply them to a broad range of application domains and industries. Emphasizes the effect of uncertainty in decision-making, as well as the interplay among high-level financial objectives, operational capabilities, and people and organizational issues. Covers topics in capacity analysis, process design, process and business innovation, inventory management, risk pooling, supply chain coordination, sustainable operations, quality management, operational risk management, pricing and revenue management. Underscores how these topics are integrated with the different functions of the firm. Case studies and simulation games provide experience in applying central concepts and techniques to solve real-world business challenges. Meets with 15.7611 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details. Summer section is primarily for Leaders for Global Operations students.
R. Levi, T. Zaman, K. Zheng
No textbook information available (Summer 2016); Textbooks (Fall 2016)

15.7611 Introduction to Operations Management
______

Undergrad (Spring)
Prereq: 6.041B or permission of instructor
Units: 4-0-5
Credit cannot also be received for15.734,15.761
______
Imparts concepts, techniques, and tools to design, analyze, and improve core operational capabilities and apply them to a broad range of application domains and industries. Emphasizes the effect of uncertainty in decision-making, as well as the interplay among high-level financial objectives, operational capabilities, and people and organizational issues. Covers topics in capacity analysis, process design, process and business innovation, inventory management, risk pooling, supply chain coordination, sustainable operations, quality management, operational risk management, pricing and revenue management. Underscores how these topics are integrated with the different functions of the firm. Case studies and simulation games provide experience in applying central concepts and techniques to solve real-world business challenges. Meets with 15.761 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
T. Zaman, K. Zheng
No textbook information available

15.762[J] Supply Chain Planning
______

Graduate (Spring)
(Same subject as1.273[J],IDS.150[J])
Prereq: 1.260 or 15.761
Units: 2-0-4
______
Focuses on effective supply chain strategies for companies that operate globally, with emphasis on how to plan and integrate supply chain components into a coordinated system. Students are exposed to concepts and models important in supply chain planning with emphasis on key tradeoffs and phenomena. Introduces and utilizes key tactics such as risk pooling and inventory placement, integrated planning and collaboration, and information sharing. Lectures, computer exercises, and case discussions introduce various models and methods for supply chain analysis and optimization. Recommended for Operations Management concentrators. First half-term subject.
Staff

15.763[J] Manufacturing System and Supply Chain Design
______

Graduate (Spring)
(Same subject as1.274[J],IDS.151[J])
Prereq: 1.260, 15.761, or 15.778
Units: 2-0-4
______
Focuses on decision making for system design, as it arises in manufacturing systems and supply chains. Students exposed to frameworks and models for structuring the key issues and trade-offs. Presents and discusses new opportunities, issues and concepts introduced by the internet and e-commerce. Introduces various models, methods and software tools for logistics network design, capacity planning and flexibility, make-buy, and integration with product development. Industry applications and cases illustrate concepts and challenges. Recommended for Operations Management concentrators. Second half-term subject.
S. C. Graves, D. Simchi-Levi

15.764[J] The Theory of Operations Management
______

Graduate (Spring) Can be repeated for credit
(Same subject as1.271[J],IDS.155[J])
Prereq: 15.081J or 6.251J, 6.436J; or permission of instructor
Units: 3-0-9
______
Provides mathematical foundations underlying the theory of operations management. Covers application domains, including inventory management, supply chain management and logistics, behavioral operations, healthcare management, service industries, pricing and revenue management, and auctions. Studies a wide range of mathematical and analytical techniques, such as dynamic programming, stochastic orders, behavioral and experimental economics, algorithms and approximations, data-driven and learning models, and mechanism design. Also provides hands-on experience in how to apply the theoretical models to solve OM problems in concrete business settings. Specific topics vary from year to year.
I. Ashlagi, D. Simchi-Levi, K. Zheng

15.765[J] Global Supply Chain Management
______

Graduate (Spring)
(Same subject as1.265[J],2.965[J],SCM.265[J])
Prereq: 1.260, 1.261, 15.761, 15.778, or permission of instructor
Units: 2-0-4
______
Focuses on the planning, processes, and activities of supply chain management for companies involved in international commerce. Students examine the end-to-end processes and operational challenges in managing global supply chains, such as the basics of global trade, international transportation, duty, taxes, trade finance and hedging, currency issues, outsourcing, cultural differences, risks and security, and green supply chains issues. Highly interactive format features student-led discussions, staged debates, and a mock trial. Includes assignments on case studies and sourcing analysis, as well as projects and a final exam.
B. Arntzen

15.767 Healthcare Lab: Introduction to Healthcare Delivery in the United States
______

Graduate (Fall)
(Subject meets with15.777)
Prereq: 15.060, 15.761; or permission of instructor
Units: 4-0-5
Lecture: MW10-11.30 (E62-250) Recitation: F1-2.30 (E62-221)
______
Focuses on the current business challenges and opportunities to deliver high quality and reasonably priced health services. Provides students the opportunity to interact with speakers and many senior executives from the health industry. Topics include healthcare reform, systematic scheduling, retail clinics, telehealth, entrepreneurship, community health, etc. Discussions include practical examples from the ongoing healthcare-related work of Sloan faculty and projects with local hospitals. Provides a broad perspective on various career paths, such as consulting, entrepreneurship, hospital management, and IT innovation. Student teams work directly with a health organization on an applied project, which includes onsite work during SIP week. Students who choose our international projects or projects out of the Boston area will do their onsite project (register for 15.777) during IAP with permission of the instructor and organization; consult instructors for information.
R. Levi, J. Wilkinson
No textbook information available

15.768 Management of Services: Concepts, Design, and Delivery
______

Graduate (Spring)
Prereq: 15.761, 15.778, or permission of instructor
Units: 3-0-6
______
Explores the use of operations tools and perspectives in the service sector, including both for-profit and not-for-profit organizations. Builds on conceptual frameworks and cases from a wide range of service operations, selected from health care, hospitality, internet services, supply chain, transportation, retailing, food service, entertainment, financial services, humanitarian services, government services, and others.
C. Fine, Z. Ton

15.769 Operations Strategy
______

Graduate (Fall, Spring)
Prereq: 15.761, 15.778, or permission of instructor
Units: 3-0-6
Lecture: TR8.30-10 (E62-250)
______
Provides unifying framework for analyzing strategic issues in manufacturing and service operations. Covers decisions in technology, facilities, vertical integration, human resources and other strategic areas. Explores means of competition, such as cost, quality, speed, innovativeness, and how operations companies address growth. Presents students with an approach to make operations decisions in the era of outsourcing and globalization.
T. Roemer, D. B. Rosenfield, Z. Ton
Textbooks (Fall 2016)

15.770[J] Logistics Systems
______

Graduate (Fall)
(Same subject as1.260[J],IDS.730[J],SCM.260[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: MW8.30-10 (E51-315)
______
Provides an introduction to supply chain management from both analytical and practical perspectives. Taking a unified approach, students develop a framework for making intelligent decisions within the supply chain. Covers key logistics functions, such as demand planning, procurement, inventory theory and control, transportation planning and execution, reverse logistics, and flexible contracting. Explores concepts such as postponement, portfolio management, and dual sourcing. Emphasizes skills necessary to recognize and manage risk, analyze various tradeoffs, and model logistics systems.
Y. Sheffi, C. Caplice
Textbooks (Fall 2016)

15.771[J] Case Studies in Logistics and Supply Chain Management
______

Graduate (Spring)
(Same subject as1.261[J],SCM.261[J])
Prereq: Permission of instructor
Units: 3-0-6
______
A combination of lectures and cases covering the strategic, management, and operating issues in contemporary logistics and integrated supply chain management. Includes: logistics strategy; supply chain restructuring and change management; and distribution, customer service, and inventory policy.
J. Byrnes

15.772[J] D-Lab: Supply Chains
______

Undergrad (Fall)
(Same subject asEC.733[J])
Prereq: None
Units: 3-3-6
Lecture: MW10-11.30 (1-134)
______
Introduces concepts of supply chain design and planning with a focus on supply chains for products destined to improve quality of life in developing countries. Topics include demand estimation, process analysis and improvement, facility location and capacity planning, inventory management, and supply chain coordination. Also covers issues specific to emerging markets, such as sustainable supply chains, choice of distribution channels, and how to account for the value-adding role of a supply chain. Students conduct D-Lab-based projects on supply chain design or improvement.
S. C. Graves
No textbook information available

15.777 Healthcare Lab: Introduction to Healthcare Delivery in the United States
______

Graduate (Fall, IAP)
(Subject meets with15.767)
Prereq: 15.060, 15.761
Units: 4-0-11
Lecture: MW10-11.30 (E62-250) Recitation: F1-2.30 (E62-221)
______
Focuses on the current business challenges and opportunities to deliver high quality and reasonably priced health services. Provides students the opportunity to interact with speakers and many senior executives from the health industry. Topics include healthcare reform, systematic scheduling, retail clinics, telehealth, entrepreneurship, community health, etc. Discussions include practical examples from the ongoing healthcare-related work of Sloan faculty and projects with local hospitals. Provides a broad perspective on various career paths, such as consulting, entrepreneurship, hospital management, and IT innovation. Student teams work directly with a health organization on an applied project, which includes onsite work during SIP week. Students who choose our international projects or projects out of the Boston area will do their onsite project (register for 15.777) during IAP with permission of the instructor and organization; consult instructors for information.
R. Levi, J. Wilkinson
No textbook information available

15.778 Introduction to Operations Management
______

Graduate (Summer)
Prereq: None
Units: 3-0-6
______
Integrated approach to the analysis, design and management of supply networks for products and services. Provides a framework for analysis, design and operation of supply chains (SCs) that relies on fundamental concepts, such as the management of inventory, and operations and logistics planning. Discusses the value of (timely) information and of the need for collaboration and coordination between SC players. Also presents conceptual frameworks that focus on the emergence of a wide range of enabling services that are critical to the survival and growth of this class of system. Includes study and discussion of concepts, examples, and case studies from a wide range of industries. Guest speakers present personal experiences on various aspects of the service industry and supply chains. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
Consult C. Fine
No textbook information available

15.780 Stochastic Models in Business Analytics
______

Undergrad (Fall)
Prereq: 6.041B, 15.079, or permission of instructor
Units: 3-0-9
Lecture: TR11.30-1 (E62-262) Recitation: F2 (E51-325) +final
______
Introduces core concepts in data-driven stochastic modeling that inform and optimize business decisions under uncertainty. Covers stochastic models and frameworks, such as queuing theory, time series forecasting, network models, dynamic programming, and stochastic optimization. Draws on real-world applications, with several examples from retail, healthcare, logistics, supply chain, social and online networks, and sports analytics.
R. Levi, K. Zheng
No textbook information available

15.783[J] Product Design and Development
______

Graduate (Spring)
(Same subject as2.739[J])
Prereq: 2.009, 15.761, 15.778, 15.810, or permission of instructor
Units: 3-3-6
URL: http://web.mit.edu/15.783j/www/
______
Covers modern tools and methods for product design and development. Includes a cornerstone project in which teams conceive, design and prototype a physical product and/or service. Covers design thinking, product planning, identifying customer needs, concept generation, product architecture, industrial design, concept design, green design methods, and product management. Sloan students register via Sloan course bidding. Engineering students accepted via lottery based on WebSIS pre-registration.
S. Eppinger, M. C. Yang

15.784 Operations Laboratory
______

Graduate (Spring)
Prereq: None.Coreq: 15.761
Units: 2-3-4
______
Provides an interactive learning experience in implementing operations improvement. Teams of 3-5 students act as consultants on operations engagements in small- to medium-sized Boston-area organizations. Class time focuses on project management, implementation issues for and examples from company settings (particularly small ones), and team report-outs and discussions. Organizations include small manufacturing companies as well as service organizations, such as hospitals and non-profits, providing a wide range of real operational problems in various environments.
D. Rosenfield, Z. Ton

15.792[J] Global Operations Leadership Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as2.890[J],10.792[J],16.985[J])
Prereq: None
Units arranged [P/D/F]
Lecture: M EVE (4-6 PM) (E62-262)
______
Integrative forum in which worldwide leaders in business, finance, government, sports, and education share their experiences and insights with students aspiring to run global operations. Students play a large role in managing the seminar. Preference to LGO students.
T. Roemer
No textbook information available

15.794 Research Project in Operations
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Designed for Leaders for Global Operations (LGO) students in conjunction with on-site projects at LGO partner companies. Student teams work on faculty-supervised thesis research projects that deal with a specific aspect of operations. Students required to summarize their work in the context of understanding organization, leadership, teamwork, and task management in conjunction with 15.317.
T. Roemer
No textbook information available

15.795 Behavioral Decision Theories and Applications
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: W EVE (4-7 PM) (E62-550)
______
Introduces fundamental behavioral theories of human decision making and demonstrates how they impact the design of management strategies and policies. Topics include prospect theory, reference-dependence preferences, loss aversion, ambiguity aversion, regret, inter-temporal preferences, social preferences, cognitive hierarchy, bounded rationality, and adaptive learning. Studies these concepts in a wide range of applications, including pricing, supply chain management, social welfare, marketing, contract design, sustainability, and e-commerce. Discusses experimental methodologies to identify and measure various preferences and phenomena, as well as mathematical models to capture them in decision making. Content updated from year to year to include state-of-the-art research.
K. Zheng
No textbook information available

15.799 Workshop in Operations Management
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
Lecture: M11.30-1 (E62-550)
______
Presentations by faculty, doctoral students, and guest speakers of ongoing research relating to current issues in operations management, including reports of research projects (proposed or in progress) and informal discussions of recent literature dealing with subjects of special interest to participants. Primarily for doctoral students.
Staff
No textbook information available

Marketing

15.809 Marketing Management
______

Graduate (Summer)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.732,15.810,15.812
______
Marketing is a rigorous, disciplined science that applies a reasoned framework to the selection of target markets and the optimization of marketing decisions. The subject has two parts: a tactical portion and a strategic portion. The strategic portion focuses on identifying target markets. The tactical portion reviews how firms optimize profits in their chosen markets. Tactical topics include pricing, promotion, channel and product issues. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
D. Simester
No textbook information available

15.810 Marketing Management
______

Graduate (Fall, Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.732,15.809,15.812
Lecture: MW1-2.30 (E62-233)
______
Develops skills in marketing analysis and planning, and introduces key marketing ideas and phenomena, such as how to deliver benefits to customers and marketing analytics. Presents a framework for marketing analysis and enhances problem solving and decision-making abilities in these areas. Material relevant to understanding, managing, and integrating marketing concepts in managerial situations, from entrepreneurial ventures to large multinational firms, and to consulting.
Consult J. R. Hauser, B. Wernerfelt
Textbooks (Fall 2016)

15.812 Marketing Management
______

Undergrad (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.732,15.809,15.810
______
Develops skills in marketing analysis and planning, and introduces key ideas and phenomena, such as how to deliver benefits to customers. Presents a framework for analysis and enhances problem solving and decision-making abilities in these areas. Material relevant to understanding, managing, and integrating marketing concepts in managerial situations, from entrepreneurial ventures to large multinational firms and to consulting. Primarily for undergraduate and non-MBA graduate students.
J. Zhang

15.818 Pricing
______

Graduate (Fall); first half of term
Prereq: None
Units: 3-0-3
Credit cannot also be received for15.726
Lecture: TR1-2.30 (E51-315) or TR2.30-4 (E51-315)
______
Framework for understanding pricing strategies and analytics, with emphasis on entrepreneurial pricing. Topics include economic value analysis, elasticities, customization, complementary products, pricing in platform markets, and anticipating competitive responses.
C. Tucker
Textbooks (Fall 2016)

15.821 Listening to the Customer
______

Graduate (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Introduction to soft consumer research methods, useful for getting quick customer input into decisions on product design and development, strategic positioning, advertising, and branding. Covers interview techniques, observational methods, voice of the customer, focus groups, and analyses suitable for qualitative data. Introduces new information-gathering methods in development at MIT.
D. Prelec

15.822 Strategic Market Measurement
______

Graduate (Spring); second half of term
Prereq: None
Units: 3-0-3
______
Project subject teaches students how to create, carry out, interpret, and analyze a market research questionnaire. Emphasis on discovering market structure and segmentation, but students can pursue other project applications. Includes a user-oriented treatment of multivariate analysis (factor analysis, multidimensional scaling, conjoint and cluster analysis).
D. Prelec

15.828 Product Management
______

Graduate (Spring)
Prereq: 15.810
Units: 3-1-5
______
Practical introduction to the process of product management. Covers the major phases of product management: opportunity identification (customer input, generating ideas, market definition), product design and positioning, pre-market testing and forecasting, launch marketing, and life-cycle management.
Staff

15.830 Enterprise Management Lab
______

Graduate (Fall, IAP)
Prereq: None.Coreq: 15.810, 15.761, or 15.900
Units: 3-0-3
Lecture: W EVE (4-7 PM) (E62-276)
______
Lays the foundation for the Enterprise Management (EM Lab)Track by developing students' ability to apply integrated management perspectives and practices in their roles within large organizations. Lectures, faculty mentors and cross-functional teams equip students with tools and knowledge to implement this track vision through classroom and project-based activities. Small teams of students deliver quality deliverables working on live integrative projects focused on marketing, operations, and/or Strategy sourced from large organizations, both for-profit and not-for-profit. Management guest speakers from Marketing, Operations and Strategy discuss their interrelated activities. The overall goal is to promote an integrated mindset towards viewing and addressing business issues. Students must register for both the fall term and IAP. Restricted to MBA students in EM Track.
S. Chatterjee
No textbook information available

15.833 Business-to-Business Marketing
______

Graduate (Fall); second half of term
Prereq: None
Units: 3-0-3
Begins Oct 31. Lecture: TR10-11.30 (E62-250)
______
Applies marketing concepts, analyses and tools used in business-to-business (B2B) marketing. Develops an understanding of customer value management as a strategy for delivering superior value to targeted business segments while maintaining equitable returns. Focuses on B2B pricing, brand building, web and technology facilitation of the supply chain, and customer relationship management. Underscores sales force management within the context of go-to-market strategy. Discusses ethical issues and various B2B contexts, such as products and services, for-profits and non-profits, and domestic and global markets. Emphasizes applications in technology and healthcare domains. Includes value-based pricing project, case studies, applied exercises, and readings.
S. Chatterjee
No textbook information available

15.834 Marketing Strategy
______

Graduate (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Uses case studies to introduce economic tools to look systematically at marketing strategy. Topics include how to identify and leverage customer-based competitive advantages and how to use them to develop new ones.
B. Wernerfelt

15.835 Entrepreneurial Marketing
______

Graduate (Spring); second half of term
Prereq: None
Units: 3-0-3
______
Provides foundational knowledge necessary to start and run a business. Discusses basic marketing theory as it applies to entrepreneurial firms. Includes guest speakers and final project.
B. Wernerfelt

15.838 Research Seminar in Marketing
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 15.810
Units: 3-0-6
Lecture: M1-4 (E62-526) +final
______
Seminar on current marketing literature and current research interests of faculty and students. Topics such as marketing models, consumer behavior, competitive strategy, marketing experimentation, and game theory. Restricted to doctoral students.
Consult D. Prelec
No textbook information available

15.839 Workshop in Marketing
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
Lecture: M4-5.30 (E62-550)
______
Presentations by faculty, doctoral students, and guest speakers of ongoing research relating to current issues in marketing. Topics: reports of research projects (proposed or in progress) and informal discussions of recent literature dealing with subjects of special interest to participants. Restricted to doctoral students.
Staff
No textbook information available

15.840-15.843 Seminar in Marketing
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 15.810
Units arranged
15.841: TBA.
15.842: TBA.
15.843: TBA.
______
Group study of current topics related to marketing.
Staff
15.841: No textbook information available
15.842: No textbook information available
15.843: No textbook information available

15.846 Branding
______

Graduate (Spring); second half of term
Prereq: 15.810
Units: 3-0-3
______
Provides a foundation for building, managing, and defending brands at various stages in the brand life cycle. Introduces the fundamentals of brand architecture and management relevant for B2C and B2B Marketing. Examples from a variety of industries cover topics that include brand co-creation, diffusion, imitation, and authenticity. Explores theory and practice using cases and academic research. Also looks at the development of leadership branding.
R. Gosline

15.847 Consumer Behavior
______

Graduate (Spring)
Prereq: 15.810
Units: 3-0-6
______
Examines models of consumer behavior and methods for its analysis and prediction. Focuses on theories developed in marketing, psychology, and other behavioral sciences, and their role in understanding consumer preferences and decision making. Reviews theories in the context of a variety of industry applications. Students apply theories to their own market research projects.
Staff

System Dynamics

15.871 Introduction to System Dynamics
______

Graduate (Fall, Spring); first half of term
Prereq: Permission of instructor
Units: 3-0-3
Credit cannot also be received for15.736
Ends Oct 21. Lecture: MW1-2.30 (E62-262) or MW2.30-4 (E62-276) or MW1-2.30 (E51-145) or MW2.30-4 (E51-325) Recitation: F10-11.30 (E62-250) or F2.30-4 (E51-315) or F8.30-10 (E62-250) or F2.30-4 (E51-315)
______
Introduction to systems thinking and system dynamics modeling applied to strategy, organizational change, and policy design. Students use simulation models, management flight simulators, and case studies to develop conceptual and modeling skills for the design and management of high-performance organizations in a dynamic world. Case studies of successful applications of system dynamics in growth strategy, management of technology, operations, supply chains, product development, and others. Principles for effective use of modeling in the real world. Meets with 15.8741 first half of term when offered concurrently. Expectations and evaluation criteria differ for students taking half-term graduate version; consult syllabus or instructor for specific details.
D. Keith, H. Rahmandad, N. Repenning, J. Sterman
Textbooks (Fall 2016)

15.872 System Dynamics II
______

Graduate (Fall, Spring); second half of term
Prereq: 15.871
Units: 3-0-3
Credit cannot also be received for15.737
Begins Oct 31. Lecture: MW1-2.30 (E62-262) or MW2.30-4 (E62-276) Recitation: F10-11.30 (E62-250) or F2.30-4 (E51-315)
______
Continuation of 15.871, emphasizing tools and methods needed to apply systems thinking and simulation modeling successfully in complex real-world settings. Uses simulation models, management flight simulators, and case studies to deepen the conceptual and modeling skills introduced in 15.871. Through models and case studies of successful applications students learn how to use qualitative and quantitative data to formulate and test models, and how to work effectively with senior executives to implement change successfully. Prerequisite for further work in the field. Meets with 15.8741 second half of term when offered concurrently. Expectations and evaluation criteria differ for students taking half-term graduate version; consult syllabus or instructor for specific details.
J. D. Sterman, H. Rahmandad, D. Keith
Textbooks (Fall 2016)

15.8741 System Dynamics for Business Policy
______

Undergrad (Fall, Spring)
Prereq: None
Units: 3-0-9
TBA.
______
Introduction to systems thinking and system dynamics modeling applied to strategy, organizational change, and policy design. Students use simulation models, management flight simulators, and case studies to develop conceptual and modeling skills for the design and management of high-performance organizations in a dynamic world. Case studies cover successful applications of system dynamics in growth strategy, management of technology, operations, supply chains, product development, and other areas. When offered concurrently, meets with 15.871 first half of term and with 15.872 second half of term. Expectations and evaluation criteria differ for students taking the half-term graduate subjects; consult syllabus or instructor for specific details.
J. Sterman, H. Rahmandad, D. Keith
No textbook information available

15.875 Applications of System Dynamics
______

Graduate (Spring) Can be repeated for credit
Prereq: 15.872
Units: 3-0-6
______
Explores how system dynamics can help organizations achieve important goals. Student teams pair with clients to tackle a pressing issue framed by the client and its partners. In interactive classroom sessions, and via client engagement, students learn modeling and consulting skills they need to be effective. Focuses on gaining practical insight from system dynamics and its application across a wide range of organizations and challenges.
Consult J. D. Sterman

15.878 Capstone Seminar in Sustainability
______

Graduate (Spring); second half of term
Prereq: 15.913
Units: 3-0-3
______
Provides an opportunity for students to synthesize their coursework and experiences in sustainability. Involves deep intellectual exploration of fundamental debates in sustainability through classic and current readings that are essential for working in the field. Students link ideas to practice through an analysis of the industry they plan to enter after graduation.
M. Amengual

15.879 Research Seminar in System Dynamics
______

Graduate (Spring) Can be repeated for credit
Prereq: 15.872 and permission of instructor
Units: 3-0-9
______
Doctoral level seminar in system dynamics modeling, with a focus on social, economic and technical systems. Covers classic works in dynamic modeling from various disciplines and current research problems and papers. Participants critique the theories and models, often including replication, testing, and improvement of various models, and lead class discussion. Topics vary from year to year.
Consult D. Keith, J. Sterman

Strategic Management

15.900 Competitive Strategy
______

Graduate (Fall, Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.9001
Lecture: MW8.30-10 (E51-345) or MW10-11.30 (E51-345)
______
Explores a wide range of strategic problems, focusing particularly on the sources of competitive advantage and the interaction between industry structure and organizational capabilities. Introduces a wide variety of modern strategy frameworks and methodologies. Builds upon and integrates material from core topics, such as economics and organizational processes. Students taking graduate version complete additional assignments. Meets with 15.9001 when offered concurrently.
D. Sull, N. Thompson, A. Kacperczyk
No required or recommended textbooks

15.9001 Competitive Strategy
______

Undergrad (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.900
______
Explores a wide range of strategic problems, focusing particularly on the sources of competitive advantage and the interaction between industry structure and organizational capabilities. Introduces a wide variety of modern strategy frameworks and methodologies. Builds upon and integrates material from core topics, such as economics and organizational processes. Students taking graduate version complete additional assignments. Meets with 15.900 when offered concurrently.
D. Sull, N. Thompson, A. Kacperczyk

15.902 Competitive Strategy
______

Graduate (Spring); first half of term
Prereq: Permission of instructor
Units: 2-0-4
Credit cannot also be received for15.714
______
Focuses on developing skills and applying frameworks for the conduct of competitive and corporate strategy. Develops tools from earlier core courses, especially those from Strategic Marketing and Organizational Processes, and Economics. Emphasis is placed on the role of strategic commitments, social networks, strategic coherence, and adapting to environmental and technological change. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
E. Zuckerman

15.903 Managing the Modern Organization: Organizational Economics and Corporate Strategy
______

Graduate (Spring); first half of term
Prereq: 15.010 or 15.311
Units: 3-0-3
______
Focuses on how managers build and manage complex organizations to achieve strategic goals. Develops theoretical frameworks that build on 15.010 and 15.311. Applies these frameworks to corporate strategy (i.e., the design and management of the multi-business firm) and extended enterprises (i.e., the design and management of multi-firm structures such as supply chains, alliances, joint ventures, and networks).
R. Gibbons

15.904 Advanced Strategic Management
______

Graduate (Spring); second half of term
Prereq: 15.900, or permission of instructor
Units: 3-0-3
Subject Cancelled Subject Cancelled
______
Builds on 15.900 and 15.902 to explore key concepts that have shaped the field of strategic management and strategy consulting over the past several decades. Uses lectures, readings, case studies, and videos to review the evolution of strategy teaching, research, and practice; the role of randomness in strategic outcomes; the difference between strategic thinking versus planning; and enduring principles related to competitive advantage. Key themes include the role of platform strategies and services, as well as capabilities, pull mechanisms, economies of scope, and flexibility, with examples from a variety of industries. Develops an understanding of what has made some firms successful in the past as well as what managers can do to compete in an uncertain future.
M. Cusumano

15.905 Technology Strategy
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Provides a series of strategic frameworks for managing high-technology businesses. Emphasis on the development and application of conceptual models which clarify the interactions between competition, patterns of technological and market change, and the structure and development of internal firm capabilities.
J. Utterback

15.910 Innovation Strategy
______

Graduate (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Establishes a solid foundation for students interested in formulating and executing a strategy for a technology-intensive business. Clarifies the interactions among competition, patterns of technological and market change, and the development of internal firm capabilities. Topics include appropriating the returns from innovation, the role of intellectual property, cooperative and open innovation, organization of R&D activities inside the firm, and multi-sided platform strategy. Key conceptual frameworks are linked to applications in a variety of industry and case settings.
B. Roin

15.911 Entrepreneurial Strategy
______

Graduate (Spring); second half of term
Prereq: None
Units: 4-0-2
______
Provides a deep understanding of the core strategic choices facing start-up innovators, as well as a synthetic framework for the development and implementation of entrepreneurial strategy in dynamic environments. Identifies the key choices entrepreneurs make to take advantage of opportunity and the logic of particular strategic commitments that allow entrepreneurs to establish competitive advantage.
S. Stern

15.912 Strategic Management of Innovation and Entrepreneurship
______

Graduate (Spring); second half of term
Prereq: 15.910, 15.911, or permission of instructor
Units: 3-0-3
______
Provides a series of strategic frameworks for managing high-technology businesses with a particular focus on innovation and entrepreneurship, especially as it builds upon patterns of technological and market change, prior research on product development and new ventures, and the structure and development of organizational capabilities. Includes case analyses and simulations, as well as independent readings drawn from research in technological innovation, entrepreneurial management, and organizational theory.
Staff

15.913 Strategies for Sustainable Business
______

Graduate (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Develops a pragmatic, action-oriented approach to sustainability: the alignment between healthy businesses, healthy environments, healthy societies, and an economy that meets human needs. In-class simulations and role-playing provide a robust foundation for understanding sustainability challenges. Cases analyze innovative strategies for sustainable businesses and organizations. Class discussions explore how sustainability is changing existing business models and market structures, how to develop sustainable management practices, and how firms can implement those practices successfully.
M. Amengual, J. Jay, J. Sterman

15.914 Competitive Dynamics and Strategy: Winning in Technology Markets
______

Graduate (Spring)
Prereq: 15.872; 15.369, 15.567, 15.900, or 15.902
Units: 2-0-7
______
Focuses on competitive strategy in technology-driven markets. Students acquire a portfolio of models of the signature dynamics in these markets and use the models in projects with participating companies to analyze technology markets, formulate competitive strategies, and illuminate the challenges of execution. Addresses issues critical for both established incumbents and new market entrants. Restricted to graduate students.
H. B. Weil

15.915 Laboratory for Sustainable Business
______

Graduate (Spring)
Prereq: 15.913
Units: 4-0-2
______
Provides students with the opportunity to apply the concepts, theories, and tools of sustainability by working with a host organization on a real management project during the semester. Classroom lectures and simulations complement project work to give greater depth in techniques for managing sustainability. Topics include start-up dynamics, certification programs, evaluating the environmental impact of products and services, and leveraging consumers to advance sustainability.
M. Amengual, J. Jay, J. Sterman

15.928 The Sociology of Strategy
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 15.342
Units: 3-0-9
______
Doctoral seminar in theory building for social scientists interested in economic sociology, organization theory, strategic management, and related fields. Builds skills for developing social scientific theory. Focuses on assessing and developing the relevance of sociological research for key questions in strategy research: what explains the relative performance of firms and the variety of their strategies for achieving performance. Students also develop skills in evaluating academic research in this area. Restricted to doctoral students.
E. Zuckerman

15.929 Identity and Action
______

Graduate (Spring)
Prereq: 15.342
Units: 3-0-9
______
Doctoral seminar in theory building for social scientists. Primary goal is to build skills for developing social scientific theory. Secondary goals are to review and integrate a broad array of ideas concerning the foundations of identity and its relation to action, and to suggest how such issues relate to a broader set of questions in the social sciences. Students learn that any account of action is based on ascribing desires, beliefs, and opportunities to specific actors, but such actors cannot be easily explained except as a result of action by prior actors. The focus of this course is around developing this paradox and providing a foundation for resolving it. Restricted to doctoral students.
E. Zuckerman

15.933 Strategic Opportunities in Energy
______

Graduate (Fall); first half of term
Prereq: 15.900 or permission of instructor
Units: 4-0-2
Ends Oct 21. Lecture: MW EVE (4-6 PM) (E62-223)
______
Introduces the energy system in terms of sources and uses, market characteristics, and key metrics. Provides frameworks for understanding the structure and dynamics of the sector and the drivers of the energy future. Opportunities resulting from demand growth, supply challenges, environmental constraints, security of supply, technology breakthroughs, and regulation are analyzed from the perspectives of both established players and entrepreneurs. Student teams engage in projects that evaluate a segment of the energy landscape and develop a strategic prospectus for a new business opportunity.
H. B. Weil, A. J. M. Meggs
No textbook information available

15.941[J] Leadership in Real Estate
______

Graduate (Fall); first half of term
(Same subject as11.430[J])
Prereq: None
Units: 3-0-3
Ends Oct 21. Lecture: MW10.30-12 (9-357)
______
Designed to help students deepen their understanding of leadership and increase self-awareness. They examine authentic leadership styles and create goals and a learning plan to develop their capabilities. They also participate in activities to strengthen their "leadership presence" - the ability to authentically connect with people's hearts and minds. Students converse with leaders to learn from their insights, experiences, and advice. Limited to 15.
G. Schuck
Textbooks (Fall 2016)

15.949 Seminar in Strategy
______

Graduate (Fall) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Opportunity for group study by graduate students on current topics related to strategy.
Consult E. Zuckerman
No textbook information available

Special Subjects

15.S01 Special Seminar in Management
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: F8.30-12 (E51-145, E51-149, E51-315, E51-325, E51-345, E51-395)
______
No textbook information available

15.S02 Special Seminar in Management
______

Graduate (Fall, IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: R EVE (4-7 PM) (E62-250)
______
No textbook information available

15.S03 Special Seminar in Management
______

Graduate (Fall, IAP, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Ends Oct 21. Lecture: W1-4 (E62-250)
______
No textbook information available

15.S04 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: MW2.30-4 (E51-145) +final
______
Textbooks (Summer 2016); No required or recommended textbooks (Fall 2016)

15.S05 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit; second half of term
Prereq: Permission of instructor
Units arranged
Lecture: TR4-5.30 (E51-395)
______
No textbook information available

15.S06 Special Seminar in Management
______

Graduate (Fall, Spring, Summer) Can be repeated for credit; second half of term
Prereq: Permission of instructor
Units arranged
Ends Oct 21. Lecture: M4-5.30 (E51-149) or W4-5.30 (E51-149)
______
No textbook information available

15.S07 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit; second half of term
Prereq: Permission of instructor
Units arranged
Begins Oct 31. Lecture: MW8.30-10 (E51-145) or MW10-11.30 (E51-145) Recitation: F8.30-10 (E51-335) or F10-11.30 (E51-335)
______
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

15.S08 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit; first half of term
Prereq: Permission of instructor
Units arranged
Lecture: T EVE (5-8 PM) (E62-221)
______
Staff
No textbook information available

15.S09 Special Seminar in Management
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: T EVE (5.30-7.30 PM) or TBA
______
Textbooks (Fall 2016)

15.S10-15.S12 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit; second half of term
Prereq: Permission of instructor
Units arranged
15.S10: TBA.
15.S11: Lecture: M1.30-3 (E62-350)
15.S12: TBA.
______
15.S10: No textbook information available
15.S11: No textbook information available
15.S12: No textbook information available

15.S13, 15.S14 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit; first half of term
Prereq: Permission of instructor
Units arranged
15.S13: Ends Oct 21. Lecture: M EVE (6-9 PM) (E51-345)
15.S14: Ends Oct 21. Lecture: M8.30-10 (E51-395)
______
15.S13: No textbook information available
15.S14: No textbook information available

15.S15, 15.S16 Special Seminar in Management
______

Graduate (Fall, IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
15.S15: Lecture: F12-2 (E51-063)
15.S16: TBA.
______
15.S15: No textbook information available
15.S16: No textbook information available

15.S17 Special Seminar in Management
______

Graduate (Fall, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: R EVE (4-7 PM) (E62-250)
______
Textbooks (Summer 2016); No textbook information available (Fall 2016)

15.S18, 15.S19 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
15.S18: Lecture: MW10-11.30 (E51-151) +final
15.S19: TBA.
______
15.S18: No required or recommended textbooks
15.S19: No textbook information available

15.S20-15.S26 Special Seminar in Management
______

Graduate (IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
15.S20: Lecture: W1-2.30 (E62-346)
15.S22: TBA.
______
Group study of current topics related to management not otherwise included in curriculum. Coursework may continue into the following term.
Consult Sloan Educational Services
15.S20: No textbook information available
15.S21: No textbook information available
15.S22: No textbook information available
15.S24: Textbooks (Summer 2016)

15.S30-15.S33 Special Distance Learning Seminar in Management
______

Graduate (Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
15.S31: TBA.
15.S32: TBA.
______
15.S31: No textbook information available
15.S32: No textbook information available
15.S33: No textbook information available

15.S35-15.S38 Special Distance Learning Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
15.S35: TBA.
15.S36: TBA.
15.S37: TBA.
15.S38: TBA.
______
Group study through distance learning on current topics related to management.
Consult Sloan Educational Services
15.S35: No textbook information available
15.S36: No textbook information available
15.S37: No textbook information available
15.S38: No textbook information available

15.S40, 15.S41 Special Seminar in Management
______

Undergrad (IAP) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
15.S40: TBA.
______
15.S40: No textbook information available

15.S42-15.S47 Special Seminar in Management
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged
15.S42: Lecture: TR1-2.30 (56-154)
15.S43: TBA.
15.S44: TBA.
15.S45: TBA.
15.S46: TBA.
15.S47: TBA.
______
15.S42: No textbook information available
15.S43: No textbook information available
15.S44: No textbook information available
15.S45: No textbook information available
15.S46: No textbook information available
15.S47: No textbook information available

15.S50-15.S54 Special Seminar in Management
______

Graduate (Fall, IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
15.S50: TBA.
15.S53: TBA.
15.S54: TBA.
______
15.S50: No textbook information available
15.S53: No textbook information available
15.S54: No textbook information available

15.S55-15.S59 Special Seminar in Management
______

Graduate (IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
15.S55: TBA.
______
15.S55: No textbook information available

15.S60-15.S65 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
15.S61: TBA.
15.S63: TBA.
15.S64: TBA.
15.S65: TBA.
______
15.S61: No textbook information available
15.S63: No textbook information available
15.S64: No textbook information available
15.S65: No textbook information available

15.S66-15.S69 Special Seminar in Management
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
15.S66: TBA.
15.S67: Lecture: W9-12 (E51-390)
______
15.S66: No textbook information available
15.S67: No textbook information available
15.S68: No textbook information available

15.S70-15.S75 Special Seminar in Management
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
15.S72: Lecture: TR4-5.30 (E51-335) Recitation: F12 (E51-335) +final
15.S73: TBA.
15.S74: TBA.
15.S75: TBA.
______
Group study of current topics related to management not otherwise included in curriculum.
Consult Sloan Educational Services
15.S72: No textbook information available
15.S73: No textbook information available
15.S74: No textbook information available
15.S75: No textbook information available

Thesis, Research, and Practice

15.UR Undergraduate Research in Management
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually

15.URG Undergraduate Studies in Management
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Participation in the work of a research group which includes such activities as independent study of the literature, direct involvement in the group's research (commensurate with the student's skills and preparation), or project work under an individual faculty member possibly extending over more than one term. Admission by arrangement with individual faculty member. Requires written project report.
J. S. Carroll
Textbooks arranged individually

15.950 Independent Study in Management
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
No textbook information available

15.951 Independent Study in Management
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Advanced work, special investigation or application of a management topic, on an individual basis, under faculty supervision. May include readings, conferences, laboratory and fieldwork, and reports. Projects require prior approval, as well as a written proposal and a final report.
M. Hanlon
No textbook information available

15.952 Curricular Practical Training
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units: 0-1-0 [P/D/F]
TBA.
______
For Course 15 undergraduate students participating in management curriculum-related off-campus work experiences. Students must have an employment offer from a company or organization and must find a Sloan faculty supervisor before enrolling. Consult Sloan Undergraduate Education Office
M. Hanlon
No textbook information available

15.960 Independent Study in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No textbook information available

15.961 Independent Study in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Advanced work, special investigation or application of a management topic, on an individual basis, under faculty supervision. May include readings, conferences, laboratory and fieldwork, and reports. Projects require prior approval, as well as a written proposal and a final report.
Consult Sloan Educational Services
No textbook information available

15.962 Pre-Thesis Research
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Pre-thesis research conducted under faculty supervision; advance approval of project proposal required. Restricted to PhD students.
Consult H. Ross
No textbook information available

15.998 Independent Group Study in Action Learning
______

Graduate (Fall, IAP, Spring, Summer)
Prereq: None
Units arranged
TBA.
______
Team-based opportunities for application management tools, under faculty supervision, on dynamic projects that provide a wide array of operational challenges facing organizations around the world. May include travel to on-site locales. Projects require prior approval, as well as a written proposal and a final report.
Consult T. Walor
No textbook information available

15.999 Curricular Practical Training (CPT)
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
15.999: TBA.
______
Students participate in off-campus work or internship experience and apply topics of management and/or culture to their experience. Requirements include mandatory attendance at one workshop and a written deliverable. Students must have a formal employment offer prior to enrolling. Restricted to MIT Sloan students who have been in legal F1 status for nine consecutive months and who wish to work in the United States in an area related to their field of study. Additional restrictions may apply.
Consult Sloan Educational Services
15.999: No textbook information available

15.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Research and writing of thesis; to be arranged by the student with supervising committee.
Consult Sloan Educational Services
Textbooks arranged individually


left arrow|15.00-15.299|15.30-15.699|15.70-15.999 plus UROP and Thesis|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 16: Aeronautics and Astronautics
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Course 16: Aeronautics and Astronautics
Fall 2016


16.00A[J] Fundamentals of Engineering Design: Explore Space, Sea and Earth
______

Undergrad (Spring)
Not offered regularly; consult department
(Same subject as2.00A[J])
Prereq: Physics I (GIR), Calculus I (GIR)
Units: 3-3-3
______
Student teams formulate and complete space/earth/ocean exploration-based design projects with weekly milestones. Introduces core engineering themes, principles, and modes of thinking. Specialized learning modules enable teams to focus on the knowledge required to complete their projects, such as machine elements, electronics, design process, visualization and communication. Includes exercises in written and oral communication and team building. Examples of projects include surveying a lake for millfoil, from a remote controlled aircraft, and then sending out robotic harvesters to clear the invasive growth; and exploration to search for the evidence of life on a moon of Jupiter, with scientists participating through teleoperation and supervisory control of robots. Enrollment limited; preference to freshmen.
A. H. Techet, D. Newman

16.00 Introduction to Aerospace and Design
______

Undergrad (Spring)
Prereq: None
Units: 3-1-5
URL: http://web.mit.edu/16.00/
______
The fundamental concepts and approaches of aerospace engineering are highlighted through lectures on aeronautics, astronautics, and design. Active learning aerospace modules make use of information technology. Student teams are immersed in a hands-on, lighter-than-air (LTA) vehicle design project where they design, build, and fly radio-controlled LTA vehicles. The connections between theory and practice are realized in the design exercises. Required design reviews precede the LTA race competition. The performance, weight, and principle characteristics of the LTA vehicles are estimated and illustrated using physics, mathematics, and chemistry known to freshmen, the emphasis being on the application of this knowledge to aerospace engineering and design rather than on exposure to new science and mathematics. Includes exercises in written and oral communication and team building.
J. A. Hoffman, R. J. Hansman

16.001 Unified Engineering: Materials and Structures
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR);Coreq: 16.002; 18.03 or 18.034
Units: 5-1-6
TR classroom is 32-144. Lecture: MRF9,T10 (32-141) Lab: TBA Recitation: W9 (32-141) +final
______
Presents fundamental principles and methods of materials and structures for aerospace engineering, and engineering analysis and design concepts applied to aerospace systems. Topics include statics; analysis of trusses; analysis of statically determinate and indeterminate systems; stress-strain behavior of materials; analysis of beam bending, buckling, and torsion; material and structural failure, including plasticity, fracture, fatigue, and their physical causes. Experiential lab and aerospace system projects provide additional aerospace context.
R. Radovitzky, D. L. Darmofal
Textbooks (Fall 2016)

16.002 Unified Engineering: Signals and Systems
______

Undergrad (Fall)
Prereq: Calculus II (GIR);Coreq: 16.001; Physics II (GIR); 18.03 or 18.034
Units: 5-1-6
TR classroom is 32-144. Lecture: MTRF10 (32-141) Lab: TBA Recitation: W10 (32-141) +final
______
Presents fundamental principles and methods of signals and systems for aerospace engineering, and engineering analysis and design concepts applied to aerospace systems. Topics include linear and time invariant systems; convolution; transform analysis; and modulation, filtering, and sampling. Experiential lab and aerospace system projects provide additional aerospace context.
K. E. Willcox, D. L. Darmofal
Textbooks (Fall 2016)

16.003 Unified Engineering: Fluid Dynamics
______

Undergrad (Spring)
Prereq: Calculus II (GIR); Physics II (GIR);18.03 or 18.034;Coreq: 16.004
Units: 5-1-6
______
Presents fundamental principles and methods of fluid dynamics for aerospace engineering, and engineering analysis and design concepts applied to aerospace systems. Topics include aircraft and aerodynamic performance, conservation laws for fluid flows, quasi-one-dimensional compressible flows, shock and expansion waves, streamline curvature, potential flow modeling, an introduction to three-dimensional wings and induced drag. Experiential lab and aerospace system projects provide additional aerospace context.
D. L. Darmofal

16.004 Unified Engineering: Thermodynamics
______

Undergrad (Spring)
Prereq: Calculus II (GIR); Physics II (GIR);18.03 or 18.034;Coreq: 16.003; Chemistry (GIR)
Units: 5-1-6
______
Presents fundamental principles and methods of thermodynamics for aerospace engineering, and engineering analysis and design concepts applied to aerospace systems. Topics include thermodynamic state of a system, forms of energy, work, heat, the first law of thermodynamics, heat engines, reversible and irreversible processes, entropy and the second law of thermodynamics, ideal and non-ideal cycle analysis, two-phase systems, and introductions to thermochemistry and heat transfer. Experiential lab and aerospace system projects provide additional aerospace context.
Z. S. Spakovszky, D. L. Darmofal

Core Undergraduate Subjects

16.06 Principles of Automatic Control
______

Undergrad (Fall)
Prereq: 16.002; 16.003 or 16.004
Units: 3-1-8
Lecture: MW1 (32-155) Lab: F1 (33-319) or F2 (33-319) Recitation: T11 (37-212) or T2 (37-212) +final
______
Introduction to design of feedback control systems. Properties and advantages of feedback systems. Time-domain and frequency-domain performance measures. Stability and degree of stability. Root locus method, Nyquist criterion, frequency-domain design, and some state space methods. Strong emphasis on the synthesis of classical controllers. Application to a variety of aerospace systems. Hands-on experiments using simple robotic systems.
J. P. How
No required or recommended textbooks

16.07 Dynamics
______

Undergrad (Fall)
Prereq: 16.001 or 16.002; 16.003 or 16.004
Units: 4-0-8
Lecture: MWF11 (37-212) Recitation: R10 (33-419) or R11 (33-418) +final
______
Fundamentals of Newtonian mechanics. Kinematics, particle dynamics, motion relative to accelerated reference frames, work and energy, impulse and momentum, systems of particles and rigid body dynamics. Applications to aerospace engineering including introductory topics in orbital mechanics, flight dynamics, inertial navigation and attitude dynamics.
W. W. Hoburg
No required or recommended textbooks

16.09 Statistics and Probability
______

Undergrad (Spring)
Prereq: Calculus II (GIR)
Units: 4-0-8
______
Introduction to statistics and probability with applications to aerospace engineering. Covers essential topics, such as sample space, discrete and continuous random variables, probability distributions, joint and conditional distributions, expectation, transformation of random variables, limit theorems, estimation theory, hypothesis testing, confidence intervals, statistical tests, and regression.
L. A. Stirling

Mechanics and Physics of Fluids

16.100 Aerodynamics
______

Undergrad (Fall)
Prereq: 16.003, 16.004
Units: 3-1-8
F10 in room 33-419. Lecture: MWF10 (4-231) Lab: T10 (33-319) or T1 (33-319)
______
Extends fluid mechanic concepts from Unified Engineering to aerodynamic performance of wings and bodies in sub/supersonic regimes. Addresses themes such as subsonic potential flows, including source/vortex panel methods; viscous flows, including laminar and turbulent boundary layers; aerodynamics of airfoils and wings, including thin airfoil theory, lifting line theory, and panel method/interacting boundary layer methods; and supersonic and hypersonic airfoil theory. Material may vary from year to year depending upon focus of design problem.
Y. M. Marzouk
Textbooks (Fall 2016)

16.101 Topics in Fluids and Propulsion
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of department
Units arranged
TBA.
______
Provides credit for work on material in fluids or propulsion outside of regularly scheduled subjects. Intended for study abroad under either the department's Year Abroad Program or the Cambridge-MIT Exchange Program. Credit may be used to satisfy specific SB degree requirements. Requires prior approval. Consult department.
N. Roy
No textbook information available

16.110 Flight Vehicle Aerodynamics
______

Graduate (Fall)
Prereq: 16.100 or permission of instructor
Units: 3-1-8
Lecture: MWF1 (33-418)
______
Aerodynamic analysis of flight vehicles using analytical, numerical, and experimental techniques separately and in combination. Matched asymptotic expansions. Farfield behavior. Finite wing theory. Trefftz-plane analysis. Laminar and turbulent boundary layers. Slender body theory. Calculation and measurement of drag components. Aerodynamic stability derivatives.
D. L. Darmofal
Textbooks (Fall 2016)

16.120 Compressible Internal Flow and Aeroacoustics
______

Graduate (Spring)
Prereq: 2.25 or permission of instructor
Units: 3-0-9
______
Internal compressible flow and fundamentals of acoustics and aerodynamic sound with applications in turbomachinery and propulsion systems. Quasi-one-dimensional compressible flow (channel flow) and extensions, including effects of shock waves, friction, energy and mass addition, swirl, and flow non-uniformity. Unsteady compressible flow, theory of sound, sources of sound and wave propagation, Lighthill's acoustic analogy, and characterization and estimation of noise sources encountered in turbomachinery and aircraft applications.
E. M. Greitzer, W. L. Harris

16.121 Analytical Subsonic Aerodynamics
(New)
______

Graduate (Fall); partial term
Prereq: 2.25, 18.085, or permission of instructor
Units: 3-0-3
Begins Oct 24. Lecture: MW9.30-11 (33-422)
______
Analysis of external inviscid, subsonic, flow over aerodynamic thin airfoils and slender lifting bodies. Analyses formulated using singular perturbation and multiple scale methods. Linearized theory. Similarity. Rayleigh-Janzen method. Prandtl-Glauert method. Göthert similarity rule. Subsonic flow past a wave-shaped wall.
W. L. Harris
No required or recommended textbooks

16.122 Analytical Subsonic Aerodynamics
______

Graduate (Spring); partial term
Prereq: 2.25, 18.085, or permission of instructor
Units: 3-0-3
______
External compressible subsonic flows for aerodynamic applications. Two and three dimensional flows. Flows with axial symmetry. Flows past a wave-shaped wall. Slender aerodynamic bodies. Similarity rules and higher approximations for similarity rules. Solutions obtained by regular and singular perturbation methods. Comparisons of experimental, computational and analytical results.
W. L. Harris

16.13 Aerodynamics of Viscous Fluids
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 16.100, 16.110, or permission of instructor
Units: 3-0-9
______
Boundary layers as rational approximations to the solutions of exact equations of fluid motion. Physical parameters influencing laminar and turbulent aerodynamic flows and transition. Effects of compressibility, heat conduction, and frame rotation. Influence of boundary layers on outer potential flow and associated stall and drag mechanisms. Numerical solution techniques and exercises.
M. Drela

Materials and Structures

16.20 Structural Mechanics
______

Undergrad (Spring)
Prereq: 16.004
Units: 5-0-7
URL: http://web.mit.edu/16.20/www/
______
Applies solid mechanics to analysis of high-technology structures. Structural design considerations. Review of three-dimensional elasticity theory; stress, strain, anisotropic materials, and heating effects. Two-dimensional plane stress and plane strain problems. Torsion theory for arbitrary sections. Bending of unsymmetrical section and mixed material beams. Bending, shear, and torsion of thin-wall shell beams. Buckling of columns and stability phenomena. Introduction to structural dynamics. Exercises in the design of general and aerospace structures.
P. A. Lagace

16.201 Topics in Materials and Structures
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of department
Units arranged
TBA.
______
Provides credit for work in materials and structures outside of regularly scheduled subjects. Intended for study abroad under either the department's Year Abroad Program or the Cambridge-MIT Exchange Program. Credit may be used to satisfy specific SB degree requirements. Requires prior approval. Consult department.
N. Roy
No textbook information available

16.202 Manufacturing with Advanced Composite Materials
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: None
Units: 1-3-2
Subject Cancelled Subject Cancelled
______
Introduces the methods used to manufacture parts made of advanced composite materials with work in the Technology Laboratory for Advanced Composites. Students gain hands-on experience by fabricating, machining, instrumenting, and testing graphite/epoxy specimens. Students also design, build, and test a composite structure as part of a design contest. Lectures supplement laboratory sessions with background information on the nature of composites, curing, composite machining, secondary bonding, and the testing of composites.
P. A. Lagace

16.221[J] Structural Dynamics and Vibrations
______

Graduate (Fall)
(Same subject as1.581[J],2.060[J])
(Subject meets with1.058)
Prereq: Permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/16.221/www/
Lecture: MWF10 (1-390) Recitation: W4 (1-246)
______
Single- and multiple-degree-of-freedom vibration problems, using matrix formulation and normal mode superposition methods. Time and frequency domain solution techniques including convolution and Fourier transforms. Applications to vibration isolation, damping treatment, and dynamic absorbers. Analysis of continuous systems by exact and approximate methods. Applications to buildings, ships, aircraft and offshore structures. Vibration measurement and analysis techniques. Students should possess basic knowledge in structural mechanics and in linear algebra. Students taking graduate version complete additional assignments.
E. Kausel, J. K. Vandiver
No textbook information available

16.223[J] Mechanics of Heterogeneous Materials
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as2.076[J])
Prereq: 2.002, 3.032, 16.20, or permission of instructor
Units: 3-0-9
______
Mechanical behavior of heterogeneous materials such as thin-film microelectro- mechanical systems (MEMS) materials and advanced filamentary composites, with particular emphasis on laminated structural configurations. Anisotropic and crystallographic elasticity formulations. Structure, properties and mechanics of constituents such as films, substrates, active materials, fibers, and matrices including nano- and micro-scale constituents. Effective properties from constituent properties. Classical laminated plate theory for modeling structural behavior including extrinsic and intrinsic strains and stresses such as environmental effects. Introduction to buckling of plates and nonlinear (deformations) plate theory. Other issues in modeling heterogeneous materials such as fracture/failure of laminated structures.
B. L. Wardle, S-G. Kim

16.225[J] Computational Mechanics of Materials
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as 2.099[J])
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Formulation of numerical (finite element) methods for the analysis of the nonlinear continuum response of materials. The range of material behavior considered includes finite deformation elasticity and inelasticity. Numerical formulation and algorithms include variational formulation and variational constitutive updates; finite element discretization; constrained problems; time discretization and convergence analysis. Strong emphasis on the (parallel) computer implementation of algorithms in programming assignments. The application to real engineering applications and problems in engineering science are stressed throughout. Experience in either C++, C, or Fortran required.
R. Radovitzky

16.230[J] Plates and Shells: Static and Dynamic Analysis
______

Graduate (Spring)
(Same subject as2.081[J])
Prereq: 2.071, 2.080, or permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/16.230/home.html
______
Stress-strain relations for plate and shell elements. Differential equations of equilibrium. Energy methods and approximate solutions. Bending and buckling of rectangular plates. Post-buckling and ultimate strength of cold formed sections and typical stiffened panels used in aerospace, civil, and mechanical engineering; offshore technology; and ship building. Geometry of curved surfaces. General theory of elastic, axisymmetric shells and their equilibrium equations. Buckling, crushing and bending strength of cylindrical shells with applications. Propagation of 1-D elastic waves in rods, geometrical and material dispersion. Plane, Rayleigh surface, and 3-D waves. 1-D plastic waves. Response of plates and shells to high-intensity loads. Dynamic plasticity and fracture. Application to crashworthiness and impact loading of structures.
T. Sapsis

Information and Control Engineering

16.30 Feedback Control Systems
______

Undergrad (Fall)
(Subject meets with16.31)
Prereq: 16.06 or 6.302
Units: 4-1-7
Lecture: MWF11 (4-237) Lab: TBA Recitation: F1 (33-419) +final
______
Reviews classical control design using root locus and frequency domain methods (Nyquist diagrams and Bode plots). Studies state-space representation of dynamic systems, including model realizations, controllability, and observability. Introduces the state-space approach to control system analysis and synthesis, including full state feedback using pole placement, state estimation, and the design of dynamic control laws. Also covers performance limitations and robustness. Extensive use of computer-aided control design tools. Applications to various aerospace systems including navigation, guidance, and control of vehicles. Students taking the graduate version complete additional assignments.
S. Karaman
Textbooks (Fall 2016)

16.301 Topics in Control, Dynamics, and Automation
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of department
Units arranged
TBA.
______
Provides credit for work on material in control and/or dynamics and/or automation outside of regularly scheduled subjects. Intended for study abroad under either the department's Year Abroad Program or the Cambridge-MIT Exchange Program. Credit may be used to satisfy specific SB degree requirements. Requires prior approval. Consult department.
N. Roy
No textbook information available

16.31 Feedback Control Systems
______

Graduate (Fall)
(Subject meets with16.30)
Prereq: 16.06 or 6.302
Units: 3-1-8
Lecture: MWF11 (4-237) Lab: TBA +final
______
Graduate-level version of 16.30; see description under 16.30. Includes additional homework questions, laboratory experiments, and a term project beyond 16.30 with a particular focus on the material associated with state-space realizations of MIMO transfer function (matrices); MIMO zeros, controllability, and observability; stochastic processes and estimation; limitations on performance; design and analysis of dynamic output feedback controllers; and robustness of multivariable control systems.
S. Karaman
Textbooks (Fall 2016)

16.322 Stochastic Estimation and Control
______

Graduate (Fall)
Prereq: 16.31; 6.041B, 6.431B, or 16.09
Units: 3-0-9
Lecture: MW1-2.30 (33-319)
______
Estimation and control of dynamic systems. Brief review of probability and random variables. Classical and state-space descriptions of random processes and their propagation through linear systems. Frequency domain design of filters and compensators. The Kalman filter to estimate the states of dynamic systems. Conditions for stability of the filter equations.
N. Roy
Textbooks (Fall 2016)

16.323 Principles of Optimal Control
______

Graduate (Spring)
Prereq: 18.085, 16.31
Units: 3-0-9
______
Studies basic optimization and the principles of optimal control. Considers deterministic and stochastic problems for both discrete and continuous systems. Solution methods include numerical search algorithms, model predictive control, dynamic programming, variational calculus, and approaches based on Pontryagin's maximum principle. Includes many examples and applications of the theory.
S. R. Hall, J. P. How

16.333 Aircraft Stability and Control
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 16.31 or permission of instructor
Units: 3-0-9
______
Brief review of applied aerodynamics and modern approaches in aircraft stability and control. Static stability and trim. Stability derivatives and characteristic longitudinal and lateral-directional motions. Physical effects of wing, fuselage, and tail on aircraft motion. Flight vehicle stabilization by classical and modern control techniques. Time and frequency domain analysis of control system performance. Human pilot models and pilot-in-the-loop control with applications. V/STOL stability, dynamics, and control during transition from hover to forward flight. Parameter sensitivity and handling quality analysis of aircraft through variable flight conditions. Brief discussion of motion at high angles-of-attack, roll coupling, and other nonlinear flight regimes.
E. Frazzoli

16.338[J] Dynamic Systems and Control
______

Graduate (Spring)
(Same subject as6.241[J])
Prereq: 6.003, 18.06
Units: 4-0-8
______
Linear, discrete- and continuous-time, multi-input-output systems in control, related areas. Least squares and matrix perturbation problems. State-space models, modes, stability, controllability, observability, transfer function matrices, poles and zeros, and minimality. Internal stability of interconnected systems, feedback compensators, state feedback, optimal regulation, observers, and observer-based compensators. Measures of control performance, robustness issues using singular values of transfer functions. Introductory ideas on nonlinear systems. Recommended prerequisite: 6.302.
M. A. Dahleh, A. Megretski, E. Frazzoli

16.343 Spacecraft and Aircraft Sensors and Instrumentation
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Covers fundamental sensor and instrumentation principles in the context of systems designed for space or atmospheric flight. Systems discussed include basic measurement system for force, temperature, pressure; navigation systems (Global Positioning System, Inertial Reference Systems, radio navigation), air data systems, communication systems; spacecraft attitude determination by stellar, solar, and horizon sensing; remote sensing by incoherent and Doppler radar, radiometry, spectrometry, and interferometry. Also included is a review of basic electromagnetic theory and antenna design and discussion of design considerations for flight. Alternate years.
K. Cahoy, R. J. Hansman

16.346 Astrodynamics
______

Graduate (Spring)
Prereq: 18.03
Units: 3-0-9
______
Fundamentals of astrodynamics; the two-body orbital initial-value and boundary-value problems with applications to space vehicle navigation and guidance for lunar and planetary missions with applications to space vehicle navigation and guidance for lunar and planetary missions including both powered flight and midcourse maneuvers. Topics include celestial mechanics, Kepler's problem, Lambert's problem, orbit determination, multi-body methods, mission planning, and recursive algorithms for space navigation. Selected applications from the Apollo, Space Shuttle, and Mars exploration programs.
S. E. Widnall

16.35 Real-Time Systems and Software
______

Undergrad (Spring)
Prereq: 1.00, 6.0002, or 6.005
Units: 3-0-9
______
Concepts, principles, and methods for specifying and designing real-time computer systems. Topics include concurrency, real-time execution implementation, scheduling, testing, verification, real-time analysis, and software engineering concepts. Additional topics include operating system architecture, process management, and networking.
N. Roy

16.355[J] Concepts in the Engineering of Software
______

Graduate (Spring)
(Same subject asIDS.341[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Reading and discussion on issues in the engineering of software systems and software development project design. Includes the present state of software engineering, what has been tried in the past, what worked, what did not, and why. Topics may differ in each offering, but are chosen from the software process and life cycle; requirements and specifications; design principles; testing, formal analysis, and reviews; quality management and assessment; product and process metrics; COTS and reuse; evolution and maintenance; team organization and people management; and software engineering aspects of programming languages.
N. G. Leveson

16.36 Communication Systems and Networks
______

Undergrad (Spring)
(Subject meets with16.363)
Prereq: 16.004 or 6.003; 16.09 or 6.041
Units: 3-0-9
______
Introduces the fundamentals of digital communications and networking. Topics include elements of information theory, sampling and quantization, coding, modulation, signal detection and system performance in the presence of noise. Study of data networking includes multiple access, reliable packet transmission, routing and protocols of the internet. Concepts discussed in the context of aerospace communication systems: aircraft communications, satellite communications, and deep space communications. Students taking graduate version complete additional assignments.
E. H. Modiano

16.363 Communication Systems and Networks
______

Graduate (Spring)
(Subject meets with16.36)
Prereq: 16.004 or 6.003; 16.09 or 6.041B
Units: 3-0-9
______
Introduces the fundamentals of digital communications and networking, focusing on the study of networks, including protocols, performance analysis, and queuing theory. Topics include elements of information theory, sampling and quantization, coding, modulation, signal detection and system performance in the presence of noise. Study of data networking includes multiple access, reliable packet transmission, routing and protocols of the internet. Concepts discussed in the context of aerospace communication systems: aircraft communications, satellite communications, and deep space communications. Students taking graduate version complete additional assignments.
E. H. Modiano

16.37[J] Data-Communication Networks
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as6.263[J])
Prereq: 6.041B or 18.204
Units: 3-0-9
______
Provides an introduction to data networks with an analytic perspective, using telephone networks, wireless networks, optical networks, the Internet and data centers as primary applications. Presents basic tools for modeling and performance analysis accompanied by elementary, meaningful simulations. Develops insights for large networks by means of simple approximations. Draws upon concepts from queueing theory and optimization.
E. Modiano, D. Shah

16.391[J] Statistics for Engineers and Scientists
______

Graduate (Fall)
(Same subject as6.434[J])
Prereq: Calculus II (GIR), 18.06, 6.431B, or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (8-205)
______
Rigorous introduction to fundamentals of statistics motivated by engineering applications. Topics include exponential families, order statistics, sufficient statistics, estimation theory, hypothesis testing, measures of performance, notions of optimality, analysis of variance (ANOVA), simple linear regression, and selected topics.
M. Win, J. N. Tsitsiklis
No textbook information available

16.395 Principles of Wide Bandwidth Communication
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.011, 16.36, or permission of instructor
Units: 3-0-9
______
Introduction to the principles of wide bandwidth wireless communication, with a focus on ultra-wide bandwidth (UWB) systems. Topics include the basics of spread-spectrum systems, impulse radio, Rake reception, transmitted reference signaling, spectral analysis, coexistence issues, signal acquisition, channel measurement and modeling, regulatory issues, and ranging, localization and GPS. Consists of lectures and technical presentations by students.
M. Z. Win

Humans and Automation

16.400 Human Systems Engineering
______

Undergrad (Fall)
(Subject meets with16.453[J],HST.518[J])
Prereq: 6.041B, 16.09, or permission of instructor
Units: 3-0-9
Lecture: TR9.30-11 (37-212)
______
Provides a fundamental understanding of human factors that must be taken into account in the design and engineering of complex aviation, space, and medical systems. Focuses primarily on derivation of human engineering design criteria from sensory, motor, and cognitive sources. Includes principles of displays, controls and ergonomics, manual control, the nature of human error, basic experimental design, and human-computer interaction in supervisory control settings. Students taking graduate version complete a research project with a final written report and oral presentation.
L. A. Stirling
Textbooks (Fall 2016)

16.401 Topics in Communication and Software
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of department
Units arranged
TBA.
______
Provides credit for student work on undergraduate-level material in communications and/or software outside of regularly scheduled subjects. Intended for study abroad under either the department's Year Abroad Program or the Cambridge-MIT Exchange Program. Credit may be used to satisfy specific SB degree requirements. Requires prior approval. Consult department.
N. Roy
No textbook information available

16.405[J] Robotics: Science and Systems
______

Undergrad (Spring) Institute Lab
(Same subject as6.141[J])
Prereq: 1.00 or 6.0001; 2.003, 6.005, 6.006, 6.009, or 16.06; or permission of instructor
Units: 2-6-4
______
Presents concepts, principles, and algorithms for sensing and computation related to the physical world. Topics include motion planning, geometric reasoning, kinematics and dynamics, state estimation, tracking, map building, manipulation, human-robot interaction, fault diagnosis, and embedded system development. Students specify and design a small-scale yet complex robot capable of real-time interaction with the natural world. Students engage in extensive written and oral communication exercises. Enrollment limited.
S. Karaman, D. Rus

16.410 Principles of Autonomy and Decision Making
______

Undergrad (Fall)
(Subject meets with16.413)
Prereq: 1.00 or 6.0002
Units: 4-0-8
Lecture: MW9.30-11 (32-123) Recitation: F11 (33-419) or F3 (33-419) +final
______
Survey of reasoning, optimization and decision making methodologies for creating highly autonomous systems and decision support aids. Focus on principles, algorithms, and their application, taken from the disciplines of artificial intelligence and operations research. Reasoning paradigms include logic and deduction, heuristic and constraint-based search, model-based reasoning, planning and execution, and machine learning. Optimization paradigms include linear programming, integer programming, and dynamic programming. Decision-making paradigms include decision theoretic planning, and Markov decision processes. Students taking graduate version complete additional assignments.
B. C. Williams
No required or recommended textbooks

16.412[J] Cognitive Robotics
______

Graduate (Spring)
(Same subject as6.834[J])
Prereq: 6.041B, 6.042, or 16.09; 16.413 or 6.034
Units: 3-0-9
______
Algorithms and paradigms for creating a wide range of robotic systems that act intelligently and robustly, by reasoning extensively from models of themselves and their world. Examples range from autonomous Mars explorers and cooperative air vehicles, to everyday embedded devices. Topics include deduction and search in real-time; temporal, decision-theoretic and contingency planning; dynamic execution and re-planning; reasoning about hidden state and failures; reasoning under uncertainty, path planning, mapping and localization, and cooperative and distributed robotics. 8 Engineering Design Points.
B. C. Williams

16.413 Principles of Autonomy and Decision Making
______

Graduate (Fall)
(Subject meets with16.410)
Prereq: 1.00, 6.0002, 6.01, or permission of instructor
Units: 3-0-9
Lecture: MW9.30-11 (33-419) Recitation: F11 (33-419) +final
______
Graduate-level version of 16.410; see description under 16.410. Additional material on reasoning under uncertainty and machine learning, including hidden Markov models, graphical models and Bayesian networks, computational learning theory, reinforcement learning, decision tree learning and support vector machines. Assignments include the application of autonomy algorithms to practical aerospace systems, as well as more advanced programming assignments.
B. C. Williams
No required or recommended textbooks

16.420 Planning Under Uncertainty
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 16.413
Units: 3-0-9
______
Concepts, principles, and methods for planning with imperfect knowledge. Topics include state estimation, planning in information space, partially observable Markov decision processes, reinforcement learning and planning with uncertain models. Students will develop an understanding of how different planning algorithms and solutions techniques are useful in different problem domains. Previous coursework in artificial intelligence and state estimation strongly recommended.
Staff

16.422 Human Supervisory Control of Automated Systems
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-1-8
______
Principles of supervisory control and telerobotics. Different levels of automation are discussed, as well as the allocation of roles and authority between humans and machines. Human-vehicle interface design in highly automated systems. Decision aiding. Trade-offs between human control and human monitoring. Automated alerting systems and human intervention in automatic operation. Enhanced human interface technologies such as virtual presence. Performance, optimization, and social implications of the human-automation system. Examples from aerospace, ground, and undersea vehicles, robotics, and industrial systems.
J. A. Shah

16.423[J] Aerospace Biomedical and Life Support Engineering
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject asHST.515[J],IDS.940[J])
Prereq: 16.400, 16.06, or permission of instructor
Units: 3-1-8
______
Fundamentals of human performance, physiology, and life support impacting engineering design and aerospace systems. Topics include effects of gravity on the muscle, skeletal, cardiovascular, and neurovestibular systems; human/pilot modeling and human/machine design; flight experiment design; and life support engineering for extravehicular activity (EVA). Case studies of current research are presented. Assignments include a design project, quantitative homework sets, and quizzes emphasizing engineering and systems aspects.
D. J. Newman

16.430[J] Sensory-Neural Systems: Spatial Orientation from End Organs to Behavior and Adaptation
______

Graduate (Spring)
(Same subject asHST.514[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces sensory systems,and multi-sensory fusion using the vestibular and spatial orientation systems as a model. Topics range from end organ dynamics to neural responses, to sensory integration, to behavior, and adaptation, with particular application to balance, posture and locomotion under normal gravity and space conditions. Depending upon the background and interests of the students, advanced term project topics might include motion sickness, astronaut adaptation, artificial gravity, lunar surface locomotion, vestibulo-cardiovascular responses, vestibular neural prostheses, or other topics of interest. Background in neuroscience or systems engineering preferred.
D. Merfeld, F. Karmali

16.440[J] Research Seminar: Human, Remote and Autonomous Systems in Air, Sea, and Space
______

Graduate (Fall)
(Same subject asSTS.470[J])
Prereq: 16.400, 16.453, or permission of instructor
Units: 3-0-9
Lecture: W9-12 (4-146)
______
Examines relationships between human-occupied, remotely operated, and autonomous systems in the extreme environments of the deep ocean, air, and spaceflight. Uses a mix of historical, sociological, and engineering perspectives, examines different forms of human presence in each type of system and how they relate to each other in time and space, including: physical hand-on-the stick flying, supervisory control, remote operation, systems design, programming autonomous systems, management. Emphasis on networks of people interacting in networks of organizations through networks of machines.
D. A. Mindell
Textbooks (Fall 2016)

16.453[J] Human Systems Engineering
______

Graduate (Fall)
(Same subject asHST.518[J])
(Subject meets with16.400)
Prereq: 6.041B, 16.09, or permission of instructor
Units: 3-0-9
Lecture: TR9.30-11 (37-212)
______
Provides a fundamental understanding of human factors that must be taken into account in the design and engineering of complex aviation, space, and medical systems. Focuses primarily on derivation of human engineering design criteria from sensory, motor, and cognitive sources. Includes principles of displays, controls and ergonomics, manual control, the nature of human error, basic experimental design, and human-computer interaction in supervisory control settings. Students taking graduate version complete a research project with a final written report and oral presentation.
L. A. Stirling
Textbooks (Fall 2016)

16.456[J] Biomedical Signal and Image Processing
______

Graduate (Spring)
(Same subject as6.555[J],HST.582[J])
Prereq: 6.003, 2.004, 16.004, or 18.085
Units: 3-4-5
______
Fundamentals of digital signal processing with particular emphasis on problems in biomedical research and clinical medicine. Basic principles and algorithms for data acquisition, imaging, filtering, and feature extraction. Laboratory projects provide practical experience in processing physiological data, with examples from cardiology, speech processing, and medical imaging.
J. Greenberg, E. Adalsteinsson, W. Wells

16.459 Bioengineering Journal Article Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units: 1-0-1
URL: http://web.mit.edu/16.459/www/
Lecture: F2 (33-218)
______
Each term, the class selects a new set of professional journal articles on bioengineering topics of current research interest. Some papers are chosen because of particular content, others are selected because they illustrate important points of methodology. Each week, one student leads the discussion, evaluating the strengths, weaknesses, and importance of each paper. Subject may be repeated for credit a maximum of four terms. Letter grade given in the last term applies to all accumulated units of 16.459.
J. A. Hoffman, C. M. Oman, L. A. Stirling
No textbook information available

16.470 Statistical Methods in Experimental Design
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.041B, 16.09, or permission of instructor
Units: 3-0-9
______
Statistically based experimental design inclusive of forming hypotheses, planning and conducting experiments, analyzing data, and interpreting and communicating results. Topics include descriptive statistics, statistical inference, hypothesis testing, parametric and nonparametric statistical analyses, factorial ANOVA, randomized block designs, MANOVA, linear regression, repeated measures models, and application of statistical software packages.
C. L. Carr

16.475 Human-Computer Interface Design Colloquium
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: None
Units: 2-0-2
Subject Cancelled Subject Cancelled
______
Provides guidance on design and evaluation of human-computer interfaces for students with active research projects. Roundtable discussion on developing user requirements, human-centered design principles, and testing and evaluating methodologies. Students present their work and evaluate each other's projects. Readings complement specific focus areas. Team participation encouraged. Open to advanced undergraduates.
Staff

Propulsion and Energy Conversion

16.50 Aerospace Propulsion
______

Undergrad (Spring)
Prereq: 16.004 or 2.005
Units: 3-0-9
______
Presents aerospace propulsive devices as systems, with functional requirements and engineering and environmental limitations. Requirements and limitations that constrain design choices. Both air-breathing and rocket engines covered, at a level which enables rational integration of the propulsive system into an overall vehicle design. Mission analysis, fundamental performance relations, and exemplary design solutions presented.
S. Barrett

16.511 Aircraft Engines and Gas Turbines
______

Graduate (Fall)
Prereq: 16.50 or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (33-422)
______
Performance and characteristics of aircraft jet engines and industrial gas turbines, as determined by thermodynamic and fluid mechanic behavior of engine components: inlets, compressors, combustors, turbines, and nozzles. Discusses various engine types, including advanced turbofan configurations, limitations imposed by material properties and stresses. Emphasizes future design trends including reduction of noise, pollutant formation, fuel consumption, and weight.
Z. S. Spakovszky
Textbooks (Fall 2016)

16.512 Rocket Propulsion
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 16.50 or permission of instructor
Units: 3-0-9
______
Chemical rocket propulsion systems for launch, orbital, and interplanetary flight. Modeling of solid, liquid-bipropellant, and hybrid rocket engines. Thermochemistry, prediction of specific impulse. Nozzle flows including real gas and kinetic effects. Structural constraints. Propellant feed systems, turbopumps. Combustion processes in solid, liquid, and hybrid rockets. Cooling; heat sink, ablative, and regenerative.
P. C. Lozano

16.522 Space Propulsion
______

Graduate (Spring)
Prereq: 16.50 or permission of instructor
Units: 3-3-6
______
Reviews rocket propulsion fundamentals. Discusses advanced concepts in rocket propulsion ranging from chemical engines to electrical engines. Topics include advanced mission analysis, physics and engineering of microthrusters, solid propellant rockets, electrothermal, electrostatic, and electromagnetic schemes for accelerating propellant. Some coverage is given of satellite power systems and their relation to propulsion systems. Laboratory work emphasizes design and characterization of electric propulsion engines.
P. C. Lozano

16.540 Internal Flows in Turbomachines
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 2.25 or permission of instructor
Units: 3-0-9
______
Internal fluid motions in turbomachines, propulsion systems, ducts and channels, and other fluid machinery. Useful basic ideas, fundamentals of rotational flows, loss sources and loss accounting in fluid devices, unsteady internal flow and flow instability, flow in rotating passages, swirling flow, generation of streamwise vorticity and three-dimensional flow, non-uniform flow in fluid components. Alternate years.
E. M. Greitzer

16.55 Ionized Gases
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 8.02 or permission of instructor
Units: 3-0-9
______
Properties and behavior of low-temperature plasmas for energy conversion, plasma propulsion, and gas lasers. Equilibrium of ionized gases: energy states, statistical mechanics, and relationship to thermodynamics. Kinetic theory: motion of charged particles, distribution function, collisions, characteristic lengths and times, cross sections, and transport properties. Gas surface interactions: thermionic emission, sheaths, and probe theory. Radiation in plasmas and diagnostics.
P. C. Lozano

Other Undergraduate Subjects

16.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually

16.EPE UPOP Engineering Practice Experience
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.EPE,2.EPE,3.EPE,6.EPE,10.EPE,16.EPE,22.EPE)
Prereq: 2.EPW or permission of instructor
Units: 0-0-1 [P/D/F]
TBA.
______
Provides sophomores with guided practice in finding opportunities and excelling in the world of practice. Building on the skills and relationships acquired in the Engineering Practice Workshop, students receive coaching to articulate goals, invoke the UPOP network of mentors and employers, identify and pursue opportunities and negotiate terms of their summer assignment. Students complete a 10-12 week internship, which includes filing three progress reports, conducting one informational interview, and possibly hosting a site visit by MIT staff. Returning to campus as juniors, UPOP students take part in reflective exercises that aid assimilation of learning objectives and reinforce the cognitive link between all aspects of the UPOP experience and disciplinary fields of study. Sequence begins in the spring of sophomore year and ends in the fall of junior year.
Staff
No textbook information available

16.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No textbook information available

16.S685 Special Subject in Aeronautics and Astronautics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Basic undergraduate topics not offered in regularly scheduled subjects. Subject to approval of faculty in charge. Prior approval required.
Consult M. A. Stuppard

16.S686 Special Subject in Aeronautics and Astronautics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Opportunity for study or lab work related to aeronautics and astronautics not covered in regularly scheduled subjects. Subject to approval of faculty in charge. Prior approval required.
Consult M. A. Stuppard
No textbook information available

16.S688 Special Subject in Aeronautics and Astronautics
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Opportunity for study or lab work related to aeronautics and astronautics but not covered in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard
No textbook information available


left arrow|16.00-16.599 plus UROP and EP|16.60-16.999 plus ThG|right arrow



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Course 16: Aeronautics and Astronautics
Fall 2016


16.621 Experimental Projects I
______

Undergrad (Fall, Spring)
Prereq: None.Coreq: 16.06 or 16.07
Units: 2-1-3
Lecture: TR1 (33-419)
______
First in a two-term sequence that addresses the conception and design of a student-defined or selected experimental research project carried out by two-person team under faculty advisement. Principles of research hypothesis formulation and assessment, experimental measurements and error analysis, and effective report writing and oral presentation, with instruction both in-class and on an individual and team basis. Selection and detailed planning of a research project, including in-depth design of experimental procedure that is then carried through to completion in 16.622.
B. L. Wardle, J. L. Craig, S. Hall, S. E. Widnall
No required or recommended textbooks

16.622 Experimental Projects II
______

Undergrad (Fall, Spring) Institute Lab
Prereq: 16.621
Units: 1-7-4
Lecture: TR1 (33-419) Lab: TR2-5 (31-GELB LAB)
______
Execution of research project experiments based on the plan developed in 16.621. Working with their faculty advisor and course staff, student teams construct their experiment, carry out measurements of the relevant phenomena, analyze the data, and then apply the results to assess the research hypothesis. Includes instruction on effective report writing and oral presentations culminating in a written final report and formal oral presentation.
B. L. Wardle, J. L. Craig, S. Hall, S. E. Widnall
No required or recommended textbooks

16.63[J] System Safety
______

Not offered academic year 2016-2017Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject asIDS.045[J])
Prereq: None
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduces the concepts of system safety and how to analyze and design safer systems. Topics include the causes of accidents in general, and recent major accidents in particular; hazard analysis, safety-driven design techniques; design of human-automation interaction; integrating safety into the system engineering process; and managing and operating safety-critical systems.
N. Leveson

16.64 Flight Measurement Laboratory
______

Undergrad (Spring)
Prereq: 16.002
Units: 2-2-2
______
Opportunity to see aeronautical theory applied in real-world environment of flight. Students assist in design and execution of simple engineering flight experiments in light aircraft. Typical investigations include determination of stability derivatives, verification of performance specifications, and measurement of navigation system characteristics. Restricted to students in Aeronautics and Astronautics.
R. J. Hansman

16.650 Engineering Leadership Lab
______

Undergrad (Fall, Spring) Can be repeated for credit
Engineering School-Wide Elective Subject.
(Offered under:6.911,16.650)
(Subject meets with6.913[J],16.667[J])
Prereq: None.Coreq: 6.912 or permission of instructor
Units: 0-2-1
Lab: F9-11 (32-124) or F1-3 (32-124) or F3-5 (32-124)
______
Exposes students to engineering frameworks, models, and cases in an interactive, experience-based environment, and hones leadership skills. Students participate in guided reflection on successes and discover opportunities for improvement in a controlled setting. Activities include design-implement activities, role-playing, simulations, case study analysis, and performance assessment by and of other students. Content throughout the term is frequently student-driven. First-year GEL Program students register for 6.911. Second-year GEL Program students register for 6.913. Preference to first-year students in the Bernard M. Gordon-MIT Engineering Leadership Program.
L. McGonagle, J. Feiler
No required or recommended textbooks

16.651 Engineering Leadership
______

Undergrad (Fall, Spring) Can be repeated for credit
Engineering School-Wide Elective Subject.
(Offered under:6.912,16.651)
Prereq: None.Coreq: 6.911 or permission of instructor
Units: 1-0-2
Lecture: M9-10.30 (5-233) or M11-12.30 (5-233) or T9-10.30 (5-233) or T11-12.30 (5-233)
______
Exposes students to the models and methods of engineering leadership within the contexts of conceiving, designing, implementing and operating products, processes and systems. Introduces models and theories, such as the Four Capabilities Framework and the Capabilities of Effective Engineering Leaders. Discusses the appropriate times and reasons to use particular models to deliver engineering success. Includes guest speakers and team projects that change from term to term. May be repeated for credit once with permission of instructor. Preference to first-year students in the Gordon Engineering Leadership Program.
J. Magarian, J. Schindall, L. McGonagle
No required or recommended textbooks

16.653 Management in Engineering
______

Undergrad (Fall)
Engineering School-Wide Elective Subject.
(Offered under:2.96,6.930,10.806,16.653)
Prereq: None
Units: 3-1-8
Lecture: MW11-12.30 (35-225) Lab: M4 (35-308) or T10 (1-273) or R4 (1-371) or F1 (1-132) or F2 (1-132)
______
Introduction and overview of engineering management. Financial principles, management of innovation, technical strategy and best management practices. Case study method of instruction emphasizes participation in class discussion. Focus is on the development of individual skills and management tools. Restricted to juniors and seniors.
H. S. Marcus, J.-H. Chun
No textbook information available

16.66 MATLAB Skills for Aeronautics and Astronautics
(16.99)
______

Undergrad (Fall); first half of term
Prereq: None
Units: 1-0-2 [P/D/F]
Ends Oct 26. Lecture: T12-2 (W31-301)
______
Introduction to basic MATLAB skills in programming, analysis, and plotting. Recommended for sophomores without previous MATLAB experience. Preference to Course 16 majors.
A. N. Marques
No required or recommended textbooks

16.662 Engineering Innovation and Design
(New)
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:2.723,6.902,16.662)
Prereq: None
Units: 3-0-3
Lecture: M EVE (7-9 PM) (32-155) Recitation: M EVE (9 PM) (32-155) or W EVE (7 PM) (2-105) or W EVE (8 PM) (2-105)
______
Project-based seminar in innovative design thinking develops students' ability to conceive, implement, and evaluate successful projects in any engineering discipline. Lectures focus on the iterative design process and techniques to enhance creative analysis. Students use this process to design and implement robust voice recognition applications using a simple web-based system. They also give presentations and receive feedback to sharpen their communication skills for high emotional and intellectual impact. Guest lectures illustrate multidisciplinary approaches to design thinking.
B. Kotelly
No textbook information available

16.667 Engineering Leadership Lab
______

Undergrad (Fall, Spring) Can be repeated for credit
Engineering School-Wide Elective Subject.
(Offered under:6.913,16.667)
(Subject meets with6.911[J],16.650[J])
Prereq: 6.911
Units: 0-2-4
Lab: F9-11 (32-124) or F1-3 (32-124) or F3-5 (32-124)
______
Exposes students to engineering frameworks, models, and cases in an interactive, experience-based environment, and hones leadership skills. Students participate in guided reflection on successes and discover opportunities for improvement in a controlled setting. Activities include design-implement activities, role-playing, simulations, case study analysis, and performance assessment by and of other students. Content throughout the term is frequently student-driven. First year GEL Program students register for 6.911. Second year GEL Program students register for 6.913. Preference to second-year students in the Bernard M. Gordon-MIT Engineering Leadership Program.
L. McGonagle, J. Feiler
No required or recommended textbooks

16.669 Project Engineering
______

Undergrad (IAP)
Engineering School-Wide Elective Subject.
(Offered under:6.914,16.669)
Prereq: 6.911 or permission of instructor
Units: 1-2-1 [P/D/F]
Credit cannot also be received for1.040
______
Students attend a four-day off-site workshop where an introduction to basic principles, methods, and tools for project management in a realistic context are covered. In teams, students create a plan for a project of their choice; past projects include Debris Removal in Haiti and Food Preparation Robot for Restaurants. Develops skills applicable to the management of complex development projects. Topics include cost-benefit analysis, resource and cost estimation, and project control and delivery. Case studies highlight projects in both hardware/construction and software. Preference to students in the Bernard M. Gordon-MIT Engineering Leadership Program.
O. de Weck

16.671[J] Leading Creative and Innovative Teams
(New)
______

Undergrad (Spring)
(Same subject as6.915[J])
Prereq: None
Units: 6-0-6
______
Empowers future leaders in technology by developing a foundation of personal and team leadership skills. Grounded in research and theory, focuses on practical leadership skills and how they can be assessed, learned, and applied to group situations in technical and engineering contexts. Focuses on how to foster original and creative thinking in groups, and how groups can successfully move creative ideas toward implementation and value creation. Balances traditional learning methods and more experiential ones, such as role play simulations and project-based learning. Enrollment limited to seating capacity of classroom. Admittance may be controlled by lottery.
D. Nino, J. Schindall

16.68 Modern Space Science and Engineering Seminar
______

Undergrad (Spring)
Prereq: None
Units: 2-0-4 [P/D/F]
______
Exposes students to the broad variety of scientific and technology experiments being carried out in space, and the complex engineering required to implement them. Fosters an appreciation for the interaction of science and engineering in the space enterprise. Specific topics vary from year to year.
J. A. Hoffman

16.680 Project in Aeronautics and Astronautics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Opportunity to work on projects related to aerospace engineering outside the department. Requires prior approval.
Consult M. A. Stuppard
No textbook information available

16.681 Topics in Aeronautics and Astronautics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Opportunity for study or laboratory project work not available elsewhere in the curriculum. Topics selected in consultation with the instructor.
Consult M. A. Stuppard
No textbook information available

16.682 Selected Topics in Aeronautics and Astronautics
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Study by qualified students. Topics selected in consultation with the instructor. Prior approval required.
Consult M. A. Stuppard
No textbook information available

16.683 Seminar in Aeronautics and Astronautics
______

Not offered academic year 2017-2018Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units: 2-0-0 [P/D/F]
TBA.
______
Speakers from campus and industry discuss current activities and advances in aeronautics and astronautics. Restricted to Course 16 students.
Consult M. A. Stuppard
Textbooks (Fall 2016)

16.687 Selected Topics in Aeronautics and Astronautics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Study by qualified students. Topics selected in consultation with the instructor. Prior approval required.
Consult M. A. Stuppard
No textbook information available

Flight Transportation

16.707[J] The History of Aviation
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject asSTS.467[J])
Prereq: Permission of Instructor
Units: 3-0-9
______
Reading course in the history of aviation, focusing on science and technology and cultural and political context. Themes include: the science of aeronautics, pilots and piloting, control systems and electronics, engineering epistemology, infrastructure, industry, government and politics, evolution of aeronautics research, culture and experience, automation and autonomy, role of MIT, literature and film. Case studies of specific systems and engineering projects. Emphasis is on book-length texts, close reading, historical methods of analyzing technological change. Study of social and political dimensions of engineering projects, examination of aviation institutions. Students prepare weekly response papers to readings, make extended presentations to class twice per semester, and submit a final research paper.
D. Mindell

16.71[J] The Airline Industry
______

Graduate (Fall)
(Same subject as1.232[J],15.054[J])
Prereq: None
Units: 3-0-9
Lecture: MW1-2.30 (35-225)
______
Overview of the global airline industry, focusing on recent industry performance, current issues and challenges for the future. Fundamentals of airline industry structure, airline economics, operations planning, safety, labor relations, airports and air traffic control, marketing, and competitive strategies, with an emphasis on the interrelationships among major industry stakeholders. Recent research findings of the MIT Global Airline Industry Program are showcased, including the impacts of congestion and delays, evolution of information technologies, changing human resource management practices, and competitive effects of new entrant airlines. Taught by faculty participants of the Global Airline Industry Program.
P. P. Belobaba, A. I. Barnett, C. Barnhart, R. J. Hansman, T. A. Kochan
Textbooks (Fall 2016)

16.715 Aerospace, Energy, and the Environment
______

Graduate (Fall)
Prereq: Chemistry (GIR); 1.060B, 2.006, 10.301,16.003, 16.004, or permission of instructor
Units: 3-0-9
Lecture: TR11-12.30 (33-319) +final
______
Addresses energy and environmental challenges facing aerospace in the 21st century. Topics include: aircraft performance and energy requirements, propulsion technologies, jet fuels and alternative fuels, lifecycle assessment of fuels, combustion, emissions, climate change due to aviation, aircraft contrails, air pollution impacts of aviation, impacts of supersonic aircraft, and aviation noise. Includes an in-depth introduction to the relevant atmospheric and combustion physics and chemistry with no prior knowledge assumed. Discussion and analysis of near-term technological, fuel-based, regulatory and operational mitigation options for aviation, and longer-term technical possibilities.
S. Barrett
No required or recommended textbooks

16.72 Air Traffic Control
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces the various aspects of present and future Air Traffic Control systems. Descriptions of the present system: systems-analysis approach to problems of capacity and safety; surveillance, including NAS and ARTS; navigation subsystem technology; aircraft guidance and control; communications; collision avoidance systems; sequencing and spacing in terminal areas; future directions and development; critical discussion of past proposals and of probable future problem areas. Requires term paper.
H. Balakrishnan

16.75[J] Airline Management
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as1.234[J])
Prereq: 16.71J
Units: 3-0-9
______
Overview of airline management decision processes, with a focus on economic issues and their relationship to operations planning models and decision support tools. Application of economic models of demand, pricing, costs, and supply to airline markets and networks. Examination of industry practice and emerging methods for fleet planning, route network design, scheduling, pricing and revenue management, with emphasis on the interactions between the components of airline management and profit objectives in competitive environments. Students participate in a competitive airline management simulation game as part of the subject requirements.
P. P. Belobaba

16.76[J] Logistical and Transportation Planning Methods
______

Graduate (Spring)
(Same subject as1.203[J],15.073[J])
Prereq: 6.041B
Units: 3-0-9
______
Quantitative techniques of operations research with emphasis on applications in transportation systems analysis (urban, air, ocean, highway, and pickup and delivery systems) and in the planning and design of logistically oriented urban service systems (e.g., fire and police departments, emergency medical services, and emergency repair services). Unified study of functions of random variables, geometrical probability, multi-server queuing theory, spatial location theory, network analysis and graph theory, and relevant methods of simulation. Computer exercises and discussions of implementation difficulties.
R. C. Larson, A. I. Barnett

16.763[J] Air Transportation Operations Research
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as1.233[J])
Prereq: 16.71, 6.431, 15.093, or permission of instructor
Units: 3-0-9
______
Presents a unified view of advanced quantitative analysis and optimization techniques applied to the air transportation sector. Considers the problem of operating and managing the aviation sector from the perspectives of the system operators (e.g., the FAA), the airlines, and the resultant impacts on the end-users (the passengers). Explores models and optimization approaches to system-level problems, airline schedule planning problems, and airline management challenges. Term paper required.
H. Balakrishnan, C. Barnhart, P. P. Belobaba

16.767 Introduction to Airline Transport Aircraft Systems and Automation
______

Graduate (IAP)
Prereq: Permission of instructor
Units: 3-2-1 [P/D/F]
______
Intensive one-week subject that uses the Boeing 767 aircraft as an example of a system of systems. Focuses on design drivers and compromises, system interactions, and human-machine interface. Morning lectures, followed by afternoon desktop simulator sessions. Critique and comparison with other transport aircraft designs. Includes one evening at Boston Logan International Airport aboard an aircraft. Enrollment limited.
C. M. Oman, B. Nield

16.781[J] Planning and Design of Airport Systems
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as1.231[J],IDS.670[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (1-379)
______
Focuses on current practice, developing trends, and advanced concepts in airport design and planning. Considers economic, environmental, and other trade-offs related to airport location, as well as the impacts of emphasizing "green" measures. Includes an analysis of the effect of airline operations on airports. Topics include demand prediction, determination of airfield capacity, and estimation of levels of congestion; terminal design; the role of airports in the aviation and transportation system; access problems; optimal configuration of air transport networks and implications for airport development; and economics, financing, and institutional aspects. Special attention to international practice and developments.
R. de Neufville, A. R. Odoni
Textbooks (Fall 2016)

Aerospace Systems

16.82 Flight Vehicle Engineering
______

Undergrad (Fall)
Prereq: Permission of instructor
Units: 3-3-6
Lecture: MW2-5 (33-419)
______
Design of an atmospheric flight vehicle to satisfy stated performance, stability, and control requirements. Emphasizes individual initiative, application of fundamental principles, and the compromises inherent in the engineering design process. Includes instruction and practice in written and oral communication, through team presentations and a written final report. Offered alternate Spring and Fall terms.
W. Hoburg, M. Drela, R. J. Hansman
No required or recommended textbooks

16.821 Flight Vehicle Development
______

Not offered academic year 2017-2018Undergrad (Spring) Institute Lab
Prereq: Permission of instructor
Units: 2-10-6
______
Focuses on implementation and operation of a flight system. Emphasizes system integration, implementation, and performance verification using methods of experimental inquiry, and addresses principles of laboratory safety. Students refine subsystem designs and fabricate working prototypes. Includes component integration into the full system with detailed analysis and operation of the complete vehicle in the laboratory and in the field, as well as experimental analysis of subsystem performance, comparison with physical models of performance and design goals, and formal review of the overall system design. Knowledge of the engineering design process is helpful. Provides instruction in written and oral communication.
R. J. Hansman, M. Drela

16.83[J] Space Systems Engineering
______

Undergrad (Spring)
(Same subject as 12.43[J])
Prereq: Permission of instructor
Units: 3-3-6
______
Design of a complete space system, including systems analysis, trajectory analysis, entry dynamics, propulsion and power systems, structural design, avionics, thermal and environmental control, human factors, support systems, and weight and cost estimates. Students participate in teams, each responsible for an integrated vehicle design, providing experience in project organization and interaction between disciplines. Includes several aspects of team communication including three formal presentations, informal progress reports, colleague assessments, and written reports. Offered alternate Fall and Spring terms.
J. A. Hoffman, A. Saenz-Otero

16.831[J] Space Systems Development
______

Not offered academic year 2016-2017Undergrad (Spring) Institute Lab
(Same subject as12.431[J])
Prereq: Permission of instructor
Units: 2-10-6
______
Students build a space system, focusing on refinement of sub-system designs and fabrication of full-scale prototypes. Sub-systems are integrated into a vehicle and tested. Sub-system performance is verified using methods of experimental inquiry, and is compared with physical models of performance and design goals. Communication skills are honed through written and oral reports. Formal reviews include the Implementation Plan Review and the Acceptance Review. Knowledge of the engineering design process is helpful.
J. A. Hoffman, A. Saenz-Otero

16.842 Fundamentals of Systems Engineering
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-0-4
Lecture: F9-11 (33-218)
______
General introduction to systems engineering using the classical V-model. Topics include stakeholder analysis, requirements definition, system architecture and concept generation, trade-space exploration and concept selection, human factors, design definition and optimization, system integration and interface management, system safety, verification and validation, and commissioning and operations. Discusses the trade-offs between performance, life-cycle cost and system operability. Readings based on systems engineering standards. Individual homework assignments apply concepts from class and contain both aeronautical and astronautical applications. Prepares students for the systems field exam in the Department of Aeronautics and Astronautics.
O. de Weck
No textbook information available

16.851 Satellite Engineering
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR12.30-2 (33-218)
______
Fundamentals of satellite engineering design, including distributed satellite. Studies orbital environment. Analyzes problems of station keeping, attitude control, communications, power generation, structural design, thermal balance, and subsystem integration. Considers trade-offs among weight, efficiency, cost, and reliability. Discusses choice of design parameters, such as size, weight, power levels, temperature limits, frequency, and bandwidth. Examples taken from current satellite systems.
K. Cahoy
Textbooks (Fall 2016)

16.852 Integrating The Lean Enterprise
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
______
Addresses some of the important issues involved with the planning, development, and implementation of lean enterprises. People, technology, process, and management dimensions of an effective lean manufacturing company are considered in a unified framework. Particular emphasis on the integration of these dimensions across the entire enterprise, including product development, production, and the extended supply chain. Analysis tools as well as future trends and directions are explored. A key component of this subject is a team project.
Staff

16.855[J] Systems Architecting Applied to Enterprises
______

Graduate (Spring)
(Same subject asIDS.336[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Focuses on principles and practices for architecting new and evolving sociotechnical enterprises. Includes reading and discussions of enterprise theory, contemporary challenges, and case studies of evolving enterprises. Covers frameworks and methods for ecosystem analysis, stakeholder analysis, architecture design and evaluation, and implementation strategies. Students work in small teams on projects to design a future architecture for a selected real-world enterprise.
D. Rhodes

16.861 Engineering Systems Analysis for Design
______

Graduate (Fall)
Engineering School-Wide Elective Subject.
(Offered under:1.146,16.861,IDS.332)
(Subject meets withIDS.333)
Prereq: 1.145 or permission of instructor
Units: 3-0-9
URL: http://msl1.mit.edu/mib/dsp/curricula.mit.edu/~dsplan/
Lecture: TR10.30-12 (1-390)
______
Covers theory and methods to identify, value, and implement flexibility in design, also known as "real options." Topics include definition of uncertainties, simulation of performance for scenarios, screening models to identify desirable flexibility, decision and lattice analysis, and multidimensional economic evaluation. Students demonstrate proficiency through an extended application to a systems design of their choice. Provides a complement to research or thesis projects. Meets with IDS.333 first half of term.
R. de Neufville
Textbooks (Fall 2016)

16.863[J] System Safety Concepts
______

Graduate (Fall)
(Same subject asIDS.340[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: F9-12 (33-422)
______
Covers important concepts and techniques in designing and operating safety-critical systems. Topics include the nature of risk, formal accident and human error models, causes of accidents, fundamental concepts of system safety engineering, system and software hazard analysis, designing for safety, fault tolerance, safety issues in the design of human-machine interaction, verification of safety, creating a safety culture, and management of safety-critical projects. Includes a class project involving the high-level system design and analysis of a safety-critical system.
N. G. Leveson
No textbook information available

16.885 Aircraft Systems Engineering
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Permission of instructor
Units: 3-1-8
Lecture: MW2-4 (33-218)
______
Holistic view of the aircraft as a system, covering basic systems engineering, cost and weight estimation, basic aircraft performance, safety and reliability, life cycle topics, aircraft subsystems, risk analysis and management, and system realization. Small student teams retrospectively analyze an existing aircraft covering: key design drivers and decisions; aircraft attributes and subsystems; operational experience. Oral and written versions of the case study are delivered. Focuses on a systems engineering analysis of the Space Shuttle. Studies both design and operations of the shuttle, with frequent lectures by outside experts. Students choose specific shuttle systems for detailed analysis and develop new subsystem designs using state of the art technology.
R. J. Hansman, W. Hoburg
No textbook information available

16.886 Air Transportation Systems Architecting
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-2-7
______
Addresses the architecting of air transportation systems. Focuses on the conceptual phase of product definition including technical, economic, market, environmental, regulatory, legal, manufacturing, and societal factors. Centers on a realistic system case study and includes a number of lectures from industry and government. Past examples include the Very Large Transport Aircraft, a Supersonic Business Jet and a Next Generation Cargo System. Identifies the critical system level issues and analyzes them in depth via student team projects and individual assignments. Overall goal is to produce a business plan and a system specifications document that can be used to assess candidate systems.
R. J. Hansman

16.888[J] Multidisciplinary System Design Optimization
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject asIDS.338[J])
Prereq: 18.085 or permission of instructor
Units: 3-1-8
______
Engineering systems modeling for design and optimization. Selection of design variables, objective functions and constraints. Overview of principles, methods and tools in multidisciplinary design optimization (MDO). Subsystem identification, development and interface design. Review of linear and non-linear constrained optimization formulations. Scalar versus vector optimization problems from systems engineering and architecting of complex systems. Heuristic search methods: Tabu search, simulated annealing, genetic algorithms. Sensitivity, tradeoff analysis and isoperformance. Multiobjective optimization and pareto optimality. Surrogate and multifidelity optimization strategies. System design for value. Specific applications from aerospace, mechanical, civil engineering and system architecture.
O. de Weck, K. E. Willcox

16.89[J] Space Systems Engineering
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject asIDS.339[J])
Prereq: 16.851 or permission of instructor
Units: 4-2-6
______
Focus on developing space system architectures. Applies subsystem knowledge gained in 16.851 to examine interactions between subsystems in the context of a space system design. Principles and processes of systems engineering including developing space architectures, developing and writing requirements, and concepts of risk are explored and applied to the project. Subject develops, documents, and presents a conceptual design of a space system including a preliminary spacecraft design.
O. de Weck

16.895[J] Engineering Apollo: The Moon Project as a Complex System
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject asSTS.471[J])
Prereq: Permission of instructor
Units: 4-0-8
______
Detailed technical and historical exploration of the Apollo project to fly humans to the moon and return them safely to Earth as an example of a complex engineering system. Emphasizes how the systems worked, the technical and social processes that produced them, mission operations, and historical significance. Guest lectures by MIT-affiliated engineers who contributed to and participated in the Apollo missions. Students work in teams on a final project analyzing an aspect of the historical project to articulate and synthesize ideas in engineering systems.
D. Mindell

Computation

16.90 Computational Methods in Aerospace Engineering
______

Undergrad (Spring)
Prereq: 16.004 or permission of instructor;Coreq: 16.09 or 6.041
Units: 3-0-9
______
Introduction to computational techniques arising in aerospace engineering. Techniques include numerical integration of systems of ordinary differential equations; numerical discretization of partial differential equations; and probabilistic methods for quantifying the impact of variability. Specific emphasis will be given to finite volume methods in fluid mechanics, and energy and finite element methods in structural mechanics.
R. Radovitzky, D. L. Darmofal

16.910[J] Introduction to Numerical Simulation
______

Graduate (Fall)
(Same subject as2.096[J],6.336[J])
Prereq: 18.03 or 18.06
Units: 3-3-6
Lecture: MW1-2.30 (32-141)
______
Introduction to computational techniques for the simulation of a large variety of engineering and physical systems. Applications are drawn from aerospace, mechanical, electrical, chemical engineering, biology, and materials science. Topics include mathematical formulations (techniques for automatic assembly of mathematical problems from physics' principles); sparse, direct and iterative solution techniques for linear systems; Newton and Homotopy methods for nonlinear problems; discretization methods for ordinary, time-periodic and partial differential equations; accelerated methods for integral equations; techniques for automatic generation of compact dynamical system models and model order reduction.
L. Daniel, J. K. White
No required or recommended textbooks

16.920[J] Numerical Methods for Partial Differential Equations
______

Graduate (Fall)
(Same subject as2.097[J],6.339[J])
Prereq: 18.03 or 18.06
Units: 3-0-9
Lecture: MW9.30-11 (4-163)
______
Covers the fundamentals of modern numerical techniques for a wide range of linear and nonlinear elliptic, parabolic, and hyperbolic partial differential and integral equations. Topics include mathematical formulations; finite difference, finite volume, finite element, and boundary element discretization methods; and direct and iterative solution techniques. The methodologies described form the foundation for computational approaches to engineering systems involving heat transfer, solid mechanics, fluid dynamics, and electromagnetics. Computer assignments requiring programming.
Q. Wang, J. K. White
No textbook information available

16.930 Advanced Topics in Numerical Methods for Partial Differential Equations
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 16.920
Units: 3-0-9
______
Covers advanced topics in numerical methods for the discretization, solution, and control of problems governed by partial differential equations. Topics include the application of the finite element method to systems of equations with emphasis on equations governing compressible, viscous flows; grid generation; optimal control of PDE-constrained systems; a posteriori error estimation and adaptivity; reduced basis approximations and reduced-order modeling. Computer assignments require programming.
Staff

16.940 Numerical Methods for Stochastic Modeling and Inference
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 16.920, 6.431; or permission of instructor
Units: 3-0-9
______
Advanced introduction to numerical methods for treating uncertainty in computational simulation. Draws examples from a range of engineering and science applications, emphasizing systems governed by ordinary and partial differential equations. Uncertainty propagation and assessment: Monte Carlo methods, variance reduction, sensitivity analysis, adjoint methods, polynomial chaos and Karhunen-Loève expansions, and stochastic Galerkin and collocation methods. Interaction of models with observational data, from the perspective of statistical inference: Bayesian parameter estimation, statistical regularization, Markov chain Monte Carlo, sequential data assimilation and filtering, and model selection.
Y. M. Marzouk

Other Graduate Subjects

16.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of department
Units arranged
TBA.
______
Program of research leading to an SM, EAA, PhD, or ScD thesis; to be arranged by the student with an appropriate MIT faculty member, who becomes thesis supervisor. Restricted to students who have been admitted into the department.
Y. M. Marzouk
Textbooks arranged individually

16.980 Advanced Project
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No textbook information available

16.981 Advanced Project
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Study, original investigation, or lab project work by qualified students. Topics selected in consultation with instructor. Prior approval required.
Consult M. A. Stuppard
No textbook information available

16.984 Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units: 2-0-0 [P/D/F]
______
Discussion of current interest topics by staff and guest speakers. Prior approval required. Restricted to Course 16 students.
Consult M. A. Stuppard

16.985[J] Global Operations Leadership Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as2.890[J],10.792[J],15.792[J])
Prereq: None
Units arranged [P/D/F]
Lecture: M EVE (4-6 PM) (E62-262)
______
Integrative forum in which worldwide leaders in business, finance, government, sports, and education share their experiences and insights with students aspiring to run global operations. Students play a large role in managing the seminar. Preference to LGO students.
T. Roemer
No textbook information available

16.990[J] Leading Creative Teams
(New)
______

Graduate (Fall, Spring)
(Same subject as6.928[J])
Prereq: None
Units: 3-1-5
Lecture: F9.30-12.30 (5-233) Lab: W3 (56-154) or F12.30 (5-233)
______
Prepares students to lead teams charged with developing creative solutions to challenging problems. Grounded in research but practical in focus, covers the development of basic leadership capabilities, such as motivating and influencing others, delegating, managing conflict, and communicating effectively; how to create, launch, develop, and adjourn teams; and how to foster creativity in small groups.
D. Nino, J. Schindall
No textbook information available

16.999 Teaching in Aeronautics and Astronautics
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
For qualified students interested in gaining teaching experience. Classroom, tutorial, or laboratory teaching under the supervision of a faculty member. Enrollment limited by availability of suitable teaching assignments. Consult department.
Y. M. Marzouk
No textbook information available

16.S198 Advanced Special Subject in Mechanics and Physics of Fluids
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled fluids subjects. Prior approval required.
Consult M. A. Stuppard

16.S199 Advanced Special Subject in Mechanics and Physics of Fluids
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled fluids subjects. Prior approval required.
Consult M. A. Stuppard

16.S298 Advanced Special Subject in Materials and Structures
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled materials and structures subjects. Prior approval required.
Consult M. A. Stuppard

16.S299 Advanced Special Subject in Materials and Structures
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled materials and structures subjects. Prior approval required.
Consult M. A. Stuppard

16.S398 Advanced Special Subject in Information and Control
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S399 Advanced Special Subject in Information and Control
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S498 Advanced Special Subject in Humans and Automation
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S499 Advanced Special Subject in Humans and Automation
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S598 Advanced Special Subject in Propulsion and Energy Conversion
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S599 Advanced Special Subject in Propulsion and Energy Conversion
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S798 Advanced Special Subject in Flight Transportation
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S799 Advanced Special Subject in Flight Transportation
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S898 Advanced Special Subject in Aerospace Systems
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard
No textbook information available

16.S899 Advanced Special Subject in Aerospace Systems
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard
No textbook information available

16.S948 Advanced Special Subject in Computation
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S949 Advanced Special Subject in Computation
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S982 Advanced Special Subject
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of department
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
M. A. Stuppard

16.S983 Advanced Special Subject
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard
No textbook information available


left arrow|16.00-16.599 plus UROP and EP|16.60-16.999 plus ThG|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 18: Mathematics
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Course 18: Mathematics
Fall 2016


General Mathematics

18.01 Calculus
______

Undergrad (Fall, Spring) Calculus I
Prereq: None
Units: 5-0-7
Credit cannot also be received for18.014,18.01A,CC.181A,ES.1801,ES.181A
URL: http://www-math.mit.edu/18.01/
Lecture: TR1,F2 (54-100) Recitation: MW10 (2-139) or MW11 (2-139) or MW12 (36-112) or MW1 (36-112, 36-153) or MW2 (36-153) +final
______
Differentiation and integration of functions of one variable, with applications. Informal treatment of limits and continuity. Differentiation: definition, rules, application to graphing, rates, approximations, and extremum problems. Indefinite integration; separable first-order differential equations. Definite integral; fundamental theorem of calculus. Applications of integration to geometry and science. Elementary functions. Techniques of integration. Polar coordinates. L'Hopital's rule. Improper integrals. Infinite series: geometric, p-harmonic, simple comparison tests, power series for some elementary functions.
Fall:J. Speck
Spring: Information: J. W. Bush
Textbooks (Fall 2016)

18.01A Calculus
______

Undergrad (Fall) Calculus I; first half of term
Prereq: Knowledge of differentiation and elementary integration
Units: 5-0-7
Credit cannot also be received for18.01,18.014,CC.181A,ES.1801,ES.181A
Ends Oct 21. Lecture: TR1,F2 (E25-111) Recitation: MW10 (2-132) or MW11 (2-132) or MW12 (2-136) or MW1 (2-136, 4-149) or MW2 (4-149)
______
Six-week review of one-variable calculus, emphasizing material not on the high-school AB syllabus: integration techniques and applications, improper integrals, infinite series, applications to other topics, such as probability and statistics, as time permits. Prerequisites: one year of high-school calculus or the equivalent, with a score of 4 or 5 on the AB Calculus test (or the AB portion of the BC test, or an equivalent score on a standard international exam), or equivalent college transfer credit, or a passing grade on the first half of the 18.01 advanced standing exam.
G. Staffilani
Textbooks (Fall 2016)

18.014 Calculus with Theory
______

Undergrad (Fall) Calculus I
Prereq: None
Units: 5-0-7
Credit cannot also be received for18.01,18.01A,CC.181A,ES.1801,ES.181A
URL: http://math.mit.edu/classes/18.014
Lecture: TR1,F2 (2-131) Recitation: MW2 (2-131) +final
______
Covers the same material as 18.01, but at a deeper and more rigorous level. Emphasizes careful reasoning and understanding of proofs. Assumes knowledge of elementary calculus. Topics: axioms for the real numbers; the Riemann integral; limits, theorems on continuous functions; derivatives of functions of one variable; the fundamental theorems of calculus; Taylor's theorem; infinite series, power series, rigorous treatment of the elementary functions.
M. McBreen
Textbooks (Fall 2016)

18.02 Calculus
______

Undergrad (Fall, Spring) Calculus II
Prereq: Calculus I (GIR)
Units: 5-0-7
Credit cannot also be received for18.022,18.024,18.02A,CC.1802,CC.182A,ES.1802,ES.182A
URL: http://math.mit.edu/classes/18.02
Lecture: TR1,F2 (26-100) Recitation: MW9 (2-142) or MW10 (2-142, 36-156, 2-136) or MW11 (36-156, 2-136, 36-144, 36-153) or MW12 (2-132, 36-153, 2-143, 2-142) or MW1 (2-143, 2-142, 2-139, 56-180, 2-146) or MW2 (2-139, 56-180, 2-146, 2-136, 2-147) or MW3 (2-136, 2-147) +final
______
Calculus of several variables. Vector algebra in 3-space, determinants, matrices. Vector-valued functions of one variable, space motion. Scalar functions of several variables: partial differentiation, gradient, optimization techniques. Double integrals and line integrals in the plane; exact differentials and conservative fields; Green's theorem and applications, triple integrals, line and surface integrals in space, Divergence theorem, Stokes' theorem; applications.
Fall:W. Minicozzi
Spring:L. Guth
Textbooks (Fall 2016)

18.02A Calculus
______

Undergrad (Fall, IAP, Spring) Calculus II
Prereq: Calculus I (GIR)
Units: 5-0-7
Credit cannot also be received for18.02,18.022,18.024,CC.1802,CC.182A,ES.1802,ES.182A
URL: http://math.mit.edu/classes/18.02A
Begins Oct 24. Lecture: TR1,F2 (E25-111) Recitation: MW10 (2-132) or MW11 (2-132) or MW12 (2-136) or MW1 (2-136, 4-149) or MW2 (4-149) +final
______
First half is taught during the last six weeks of the Fall term; covers material in the first half of 18.02 (through double integrals). Second half of 18.02A can be taken either during IAP (daily lectures) or during the second half of the Spring term; it covers the remaining material in 18.02.
N. Stoop
Textbooks (Fall 2016)

18.022 Calculus
______

Undergrad (Fall) Calculus II
Prereq: Calculus I (GIR)
Units: 5-0-7
Credit cannot also be received for18.02,18.024,18.02A,CC.1802,CC.182A,ES.1802,ES.182A
Lecture: TR1,F2 (4-270) Recitation: MW11 (2-135) or MW12 (2-131) or MW1 (2-135) or MW2 (2-143) +final
______
Calculus of several variables. Topics as in 18.02 but with more focus on mathematical concepts. Vector algebra, dot product, matrices, determinant. Functions of several variables, continuity, differentiability, derivative. Parametrized curves, arc length, curvature, torsion. Vector fields, gradient, curl, divergence. Multiple integrals, change of variables, line integrals, surface integrals. Stokes' theorem in one, two, and three dimensions.
P. I. Etingof
Textbooks (Fall 2016)

18.024 Calculus with Theory
______

Undergrad (Spring) Calculus II
Prereq: Calculus I (GIR), permission of Instructor
Units: 5-0-7
Credit cannot also be received for18.02,18.022,18.02A,CC.1802,CC.182A,ES.1802,ES.182A
______
Continues 18.014. Parallel to 18.02, but at a deeper level, emphasizing careful reasoning and understanding of proofs. Considerable emphasis on linear algebra and vector integral calculus.
M. McBreen

18.03 Differential Equations
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: None.Coreq: Calculus II (GIR)
Units: 5-0-7
Credit cannot also be received for18.034,CC.1803,ES.1803
URL: http://math.mit.edu/classes/18.03
Lecture: MWF1 (54-100) Recitation: TR10 (2-147) or TR11 (2-147, 2-139) or TR12 (2-139, 2-147) or TR1 (2-147, 2-132, 2-142) or TR2 (2-147) or TR3 (2-147) +final
______
Study of differential equations, including modeling physical systems. Solution of first-order ODEs by analytical, graphical, and numerical methods. Linear ODEs with constant coefficients. Complex numbers and exponentials. Inhomogeneous equations: polynomial, sinusoidal, and exponential inputs. Oscillations, damping, resonance. Fourier series. Matrices, eigenvalues, eigenvectors, diagonalization. First order linear systems: normal modes, matrix exponentials, variation of parameters. Heat equation, wave equation. Nonlinear autonomous systems: critical point analysis, phase plane diagrams.
Fall:J. Dunkel
Spring:L. Demanet
No required or recommended textbooks

18.031 System Functions and the Laplace Transform
______

Undergrad (IAP)
Prereq: 18.03
Units: 1-0-2 [P/D/F]
______
Studies basic continuous control theory as well as representation of functions in the complex frequency domain. Covers generalized functions, unit impulse response, and convolution; and Laplace transform, system (or transfer) function, and the pole diagram. Includes examples from mechanical and electrical engineering.
Information: J. W. Bush

18.034 Differential Equations
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: None.Coreq: Calculus II (GIR)
Units: 5-0-7
Credit cannot also be received for18.03,CC.1803,ES.1803
URL: http://math.mit.edu/classes/18.034
______
Covers much of the same material as 18.03 with more emphasis on theory. The point of view is rigorous and results are proven. Local existence and uniqueness of solutions.
T. Colding

18.04 Complex Variables with Applications
______

Undergrad (Spring)
Prereq: Calculus II (GIR); 18.03 or 18.034
Units: 4-0-8
Credit cannot also be received for18.075,18.0751
URL: http://math.mit.edu/18.04/
______
Complex algebra and functions; analyticity; contour integration, Cauchy's theorem; singularities, Taylor and Laurent series; residues, evaluation of integrals; multivalued functions, potential theory in two dimensions; Fourier analysis, Laplace transforms, and partial differential equations.
J. Orloff

18.05 Introduction to Probability and Statistics
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: Calculus I (GIR)
Units: 4-0-8
URL: http://math.mit.edu/classes/18.05
______
Elementary introduction with applications. Basic probability models. Combinatorics. Random variables. Discrete and continuous probability distributions. Statistical estimation and testing. Confidence intervals. Introduction to linear regression.
J. Orloff, D.A. Vogan

18.06 Linear Algebra
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR)
Units: 4-0-8
Credit cannot also be received for18.700
URL: http://web.mit.edu/18.06/www/
Lecture: MWF11 (54-100) Recitation: T9 (38-166) or T10 (38-166, 2-146) or T11 (38-166) or T12 (38-166) or T1 (38-166) or T2 (38-166, 2-142) or T3 (2-142) +final
______
Basic subject on matrix theory and linear algebra, emphasizing topics useful in other disciplines, including systems of equations, vector spaces, determinants, eigenvalues, singular value decomposition, and positive definite matrices. Applications to least-squares approximations, stability of differential equations, networks, Fourier transforms, and Markov processes. Uses MATLAB. Compared with 18.700, more emphasis on matrix algorithms and many applications.
Fall:C. Barwick
Spring:S. G. Johnson
Textbooks (Fall 2016)

18.062[J] Mathematics for Computer Science
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
(Same subject as6.042[J])
Prereq: Calculus I (GIR)
Units: 5-0-7
URL: http://theory.csail.mit.edu/classes/6.042
Lecture: TR2.30-4 (26-100) Recitation: WF9 (38-166) or WF10 (38-166) or WF11 (38-166) or WF12 (38-166) or WF1 (38-166) or WF2 (38-166) or WF3 (38-166) or WF4 (38-166) or WF10 (13-3101) or WF11 (13-3101) or WF12 (13-3101) or WF1 (13-3101) or WF2 (13-3101) or WF3 (13-3101) or WF4 (13-3101) or WF10 (26-168) or WF11 (26-168) or WF12 (26-168) or WF1 (26-168) or WF2 (26-168) or WF3 (26-168) or WF4 (26-168) or WF11 (24-112) or WF12 (24-112) or WF1 (24-112) or WF9 (26-168) +final
______
Elementary discrete mathematics for computer science and engineering. Emphasis on mathematical definitions and proofs as well as on applicable methods. Topics include formal logic notation, proof methods; induction, well-ordering; sets, relations; elementary graph theory; asymptotic notation and growth of functions; permutations and combinations, counting principles; discrete probability. Further selected topics include recursive definition and structural induction, state machines and invariants, integer congruences, recurrences, generating functions.
F. T. Leighton, A. R. Meyer, A. Moitra
No required or recommended textbooks

18.075 Methods for Scientists and Engineers
______

Undergrad (Spring)
(Subject meets with18.0751)
Prereq: Calculus II (GIR); 18.03
Units: 3-0-9
Credit cannot also be received for18.04
URL: http://math.mit.edu/classes/18.075
______
Covers functions of a complex variable; calculus of residues. Includes ordinary differential equations; Bessel and Legendre functions; Sturm-Liouville theory; partial differential equations; heat equation; and wave equations.
H. Cheng

18.0751 Methods for Scientists and Engineers
______

Graduate (Spring)
(Subject meets with18.075)
Prereq: Calculus II (GIR); 18.03
Units: 3-0-9
Credit cannot also be received for18.04
______
Covers functions of a complex variable; calculus of residues. Includes ordinary differential equations; Bessel and Legendre functions; Sturm-Liouville theory; partial differential equations; heat equation; and wave equations. Students in Courses 6, 8, 12, 18, and 22 must register for undergraduate version, 18.075.
H. Cheng

18.085 Computational Science and Engineering I
______

Undergrad (Fall, Spring, Summer)
(Subject meets with18.0851)
Prereq: Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9
URL: http://math.mit.edu/classes/18.085
Lecture: TR11-12.30 (2-190)
______
Review of linear algebra, applications to networks, structures, and estimation, finite difference and finite element solution of differential equations, Laplace's equation and potential flow, boundary-value problems, Fourier series, discrete Fourier transform, convolution. Frequent use of MATLAB in a wide range of scientific and engineering applications.
Fall:G. Strang
Spring:P. Saenz
Textbooks (Summer 2016); Textbooks (Fall 2016)
______
Summer 2016 Description for Computational Science and Engineering I
(Subject meets with 18.0851)
Prereq:Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9


Review of linear algebra, applications to networks, structures, and estimation, finite difference and finite element solution of differential equations, Laplace's equation and potential flow, boundary-value problems, Fourier series, discrete Fourier transform, convolution. Frequent use of MATLAB in a wide range of scientific and engineering applications.

A. Forrow, J. Slomka
Section: MWF 9:30 AM-11:00 AM Room 2-131 From 06-JUN-16 Thru 12-AUG-16
Textbooks (Spring 2016); Textbooks (Summer 2016)

18.0851 Computational Science and Engineering I
______

Graduate (Fall, Spring, Summer)
(Subject meets with18.085)
Prereq: Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9
Lecture: TR11-12.30 (2-190)
______
Review of linear algebra, applications to networks, structures, and estimation, finite difference and finite element solution of differential equations, Laplace's equation and potential flow, boundary-value problems, Fourier series, discrete Fourier transform, convolution. Frequent use of MATLAB in a wide range of scientific and engineering applications. Students in Course 18 must register for the undergraduate version, 18.085.
Fall:G. Strang
Spring:P. Saenz
Textbooks (Summer 2016); Textbooks (Fall 2016)
______
Summer 2016 Description for Computational Science and Engineering I
(Subject meets with 18.085)
Prereq:Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9


Review of linear algebra, applications to networks, structures, and estimation, finite difference and finite element solution of differential equations, Laplace's equation and potential flow, boundary-value problems, Fourier series, discrete Fourier transform, convolution. Frequent use of MATLAB in a wide range of scientific and engineering applications. Students in Course 18 must register for the undergraduate version, 18.085.

A. Forrow, J. Slomka
Section: MWF 9:30 AM-11:00 AM Room 2-131 From 06-JUN-16 Thru 12-AUG-16
Textbooks (Spring 2016); Textbooks (Summer 2016)

18.086 Computational Science and Engineering II
______

Undergrad (Spring)
(Subject meets with18.0861)
Prereq: Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9
URL: http://math.mit.edu/18086/
______
Initial value problems: finite difference methods, accuracy and stability, heat equation, wave equations, conservation laws and shocks, level sets, Navier-Stokes. Solving large systems: elimination with reordering, iterative methods, preconditioning, multigrid, Krylov subspaces, conjugate gradients. Optimization and minimum principles: weighted least squares, constraints, inverse problems, calculus of variations, saddle point problems, linear programming, duality, adjoint methods.
H. Reid

18.0861 Computational Science and Engineering II
______

Graduate (Spring)
(Subject meets with18.086)
Prereq: Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9
______
Initial value problems: finite difference methods, accuracy and stability, heat equation, wave equations, conservation laws and shocks, level sets, Navier-Stokes. Solving large systems: elimination with reordering, iterative methods, preconditioning, multigrid, Krylov subspaces, conjugate gradients. Optimization and minimum principles: weighted least squares, constraints, inverse problems, calculus of variations, saddle point problems, linear programming, duality, adjoint methods. Students in Course 18 must register for the undergraduate version, 18.086.
H. Reid

18.089 Review of Mathematics
______

Graduate (Summer)
Prereq: Permission of instructor
Units: 5-0-7
______
One-week review of one-variable calculus (18.01), followed by concentrated study covering multivariable calculus (18.02), two hours per day for five weeks. Primarily for graduate students in Course 2N. Degree credit allowed only in special circumstances.
Information: J. W. Bush
Textbooks (Summer 2016)
______
Summer 2016 Description for Review of Mathematics
Prereq:Permission of instructor
Units: 5-0-7


One-week review of one-variable calculus (18.01), followed by concentrated study covering multivariable calculus (18.02), two hours per day for five weeks. Primarily for graduate students in Course 2N. Degree credit allowed only in special circumstances.

B. Yang, C. Sauer-Ayala
Section: Schedule TBD
Textbooks (Summer 2016)

18.094[J] Teaching College-Level Science and Engineering
______

Graduate (Fall)
(Same subject as1.95[J],5.95[J],7.59[J],8.395[J])
(Subject meets with2.978)
Prereq: None
Units: 2-0-2 [P/D/F]
URL: https://wikis.mit.edu/confluence/pages/viewpage.action?pageId=110876412
Lecture: R9-11 (4-149)
______
Participatory seminar focuses on the knowledge and skills necessary for teaching science and engineering in higher education. Topics include theories of adult learning; course development; promoting active learning, problemsolving, and critical thinking in students; communicating with a diverse student body; using educational technology to further learning; lecturing; creating effective tests and assignments; and assessment and evaluation. Students research and present a relevant topic of particular interest. Appropriate for both novices and those with teaching experience.
J. Rankin
No textbook information available

18.095 Mathematics Lecture Series
______

Undergrad (IAP) Can be repeated for credit
Prereq: Calculus I (GIR)
Units: 2-0-4 [P/D/F]
URL: http://math.mit.edu/classes/18.095/
______
Ten lectures by mathematics faculty members on interesting topics from both classical and modern mathematics. All lectures accessible to students with calculus background and an interest in mathematics. At each lecture, reading and exercises are assigned. Students prepare these for discussion in a weekly problem session.
Information: J. W. Bush

18.098 Internship in Mathematics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Provides academic credit for students pursuing internships to gain practical experience in the applications of mathematical concepts and methods.
Information: J. W. Bush
No required or recommended textbooks

18.099 Independent Study
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Studies (during IAP) or special individual reading (during regular terms). Arranged in consultation with individual faculty members and subject to departmental approval.
Information: J. W. Bush
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

Analysis

18.1001 Real Analysis
______

Graduate (Fall, Spring)
(Subject meets with18.100A)
Prereq: Calculus II (GIR); or 18.014 andCoreq: Calculus II (GIR)
Units: 3-0-9
Credit cannot also be received for18.100B,18.100P,18.100Q
Lecture: MWF1 (4-163) +final
______
Textbooks (Fall 2016)

18.1002 Real Analysis
______

Graduate (Fall, Spring)
(Subject meets with18.100B)
Prereq: Calculus II (GIR); or 18.014 andCoreq: Calculus II (GIR)
Units: 3-0-9
Credit cannot also be received for18.100A,18.100Q
Lecture: MWF2 (2-190) +final
______
Textbooks (Fall 2016)

18.100A Real Analysis
______

Undergrad (Fall, Spring)
(Subject meets with18.1001)
Prereq: Calculus II (GIR); or 18.014 andCoreq: Calculus II (GIR)
Units: 3-0-9
Credit cannot also be received for18.100B,18.100P,18.100Q
Lecture: MWF1 (4-163) +final
______
Textbooks (Fall 2016)

18.100B Real Analysis
______

Undergrad (Fall, Spring)
(Subject meets with18.1002)
Prereq: Calculus II (GIR); or 18.014 andCoreq: Calculus II (GIR)
Units: 3-0-9
Credit cannot also be received for18.100A,18.100Q
URL: http://www.mit.edu/~jzahl/teaching/18100B.html
Lecture: MWF2 (2-190) +final
______
Textbooks (Fall 2016)

18.100P Real Analysis
(New)
______

Undergrad (Spring)
Prereq: Calculus II (GIR); or 18.014 andCoreq: Calculus II (GIR)
Units: 4-0-11
Credit cannot also be received for18.1001,18.100A,18.100B,18.100Q
______

18.100Q Real Analysis
(18.100C)
______

Undergrad (Fall)
Prereq: Calculus II (GIR); or 18.014 andCoreq: Calculus II (GIR)
Units: 4-0-11
Credit cannot also be received for18.1001,18.1002,18.100A,18.100B,18.100P
Lecture: TR9.30-11 (2-131) Recitation: F10 (2-131) or F3 (2-131) +final
______
Four options offered, each covering fundamentals of mathematical analysis: convergence of sequences and series, continuity, differentiability, Riemann integral, sequences and series of functions, uniformity, interchange of limit operations. Each option shows the utility of abstract concepts and teaches understanding and construction of proofs. Option A: Proofs and definitions are less abstract. Gives applications where possible. Concerned primarily with the real line. Option B: More demanding; for students with more mathematical maturity. Places more emphasis on point-set topology and n-space. Option P: 15-unit (4-0-11) variant of Option A, with further instruction and practice in written communication. Option Q: 15-unit (4-0-11) variant of Option B, with further instruction and practice in written communication. Enrollment limited in Options P and Q.
Fall:18.100A: A. P. Mattuck
18.100B: D. Jerison
18.100Q: B. Wilson

Spring:18.100A: R. Casals
18.100B: A. Lawrie
18.100P: T. Beck

Textbooks (Fall 2016)

18.101 Analysis and Manifolds
______

Undergrad (Fall)
(Subject meets with18.1011)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.101/
Lecture: MWF11 (2-143) +final
______
Introduction to the theory of manifolds: vector fields and densities on manifolds, integral calculus in the manifold setting and the manifold version of the divergence theorem. 18.901 helpful but not required.
V. W. Guillemin
Textbooks (Fall 2016)

18.1011 Analysis and Manifolds
______

Graduate (Fall)
(Subject meets with18.101)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
Lecture: MWF11 (2-143) +final
______
Introduction to the theory of manifolds: vector fields and densities on manifolds, integral calculus in the manifold setting and the manifold version of the divergence theorem. 18.9011 helpful but not required. Students in Course 18 must register for the undergraduate version, 18.101.
V. W. Guillemin
No textbook information available

18.102 Introduction to Functional Analysis
______

Undergrad (Spring)
(Subject meets with18.1021)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.102
______
Normed spaces, completeness, functionals, Hahn-Banach theorem, duality, operators. Lebesgue measure, measurable functions, integrability, completeness of L-p spaces. Hilbert space. Compact, Hilbert-Schmidt and trace class operators. Spectral theorem.
R. B. Melrose

18.1021 Introduction to Functional Analysis
______

Graduate (Spring)
(Subject meets with18.102)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
______
Normed spaces, completeness, functionals, Hahn-Banach theorem, duality, operators. Lebesgue measure, measurable functions, integrability, completeness of L-p spaces. Hilbert space. Compact, Hilbert-Schmidt and trace class operators. Spectral theorem. Students in Course 18 must register for the undergraduate version, 18.102.
R. B. Melrose

18.103 Fourier Analysis: Theory and Applications
______

Undergrad (Fall)
(Subject meets with18.1031)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.103
Lecture: MWF12 (2-139) +final
______
Roughly half the subject devoted to the theory of the Lebesgue integral with applications to probability, and half to Fourier series and Fourier integrals.
A. Lawrie
Textbooks (Fall 2016)

18.1031 Fourier Analysis: Theory and Applications
______

Graduate (Fall)
(Subject meets with18.103)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
Lecture: MWF12 (2-139) +final
______
Roughly half the subject devoted to the theory of the Lebesgue integral with applications to probability, and half to Fourier series and Fourier integrals. Students in Course 18 must register for the undergraduate version, 18.103.
A. Lawrie
Textbooks (Fall 2016)

18.104 Seminar in Analysis
______

Undergrad (Spring)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q
Units: 3-0-9
URL: http://math.mit.edu/~datchev/18.104/18.104.html
______
Students present and discuss material from books or journals. Topics vary from year to year. Instruction and practice in written and oral communication provided. Enrollment limited.
D. Jerison

18.112 Functions of a Complex Variable
______

Undergrad (Fall)
(Subject meets with18.1121)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.112
Lecture: MWF10 (56-154) +final
______
Studies the basic properties of analytic functions of one complex variable. Conformal mappings and the Poincare model of non-Euclidean geometry. Cauchy-Goursat theorem and Cauchy integral formula. Taylor and Laurent decompositions. Singularities, residues and computation of integrals. Harmonic functions and Dirichlet's problem for the Laplace equation. The partial fractions decomposition. Infinite series and infinite product expansions. The Gamma function. The Riemann mapping theorem. Elliptic functions.
T. Beck
Textbooks (Fall 2016)

18.1121 Functions of a Complex Variable
______

Graduate (Fall)
(Subject meets with18.112)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
Lecture: MWF10 (56-154) +final
______
Studies the basic properties of analytic functions of one complex variable. Conformal mappings and the Poincare model of non-Euclidean geometry. Cauchy-Goursat theorem and Cauchy integral formula. Taylor and Laurent decompositions. Singularities, residues and computation of integrals. Harmonic functions and Dirichlet's problem for the Laplace equation. The partial fractions decomposition. Infinite series and infinite product expansions. The Gamma function. The Riemann mapping theorem. Elliptic functions. Students in Course 18 must register for the undergraduate version, 18.112.
T. Beck
No textbook information available

18.116 Riemann Surfaces
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 18.112
Units: 3-0-9
Lecture: MWF9 (2-136)
______
Riemann surfaces, uniformization, Riemann-Roch Theorem. Theory of elliptic functions and modular forms. Some applications, such as to number theory.
R. Casals
No required or recommended textbooks

18.117 Topics in Several Complex Variables
______

Not offered academic year 2017-2018Graduate (Spring) Can be repeated for credit
Prereq: 18.112, 18.965
Units: 3-0-9
______
Harmonic theory on complex manifolds, Hodge decomposition theorem, Hard Lefschetz theorem. Vanishing theorems. Theory of Stein manifolds. As time permits students also study holomorphic vector bundles on Kahler manifolds.
B. Poonen

18.125 Measure Theory and Analysis
______

Graduate (Spring)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q
Units: 3-0-9
URL: http://math.mit.edu/classes/18.125/
______
Provides a rigorous introduction to Lebesgue's theory of measure and integration. Covers material that is essential in analysis, probability theory, and differential geometry.
S. Becker-Kahn

18.137 Topics in Geometric Partial Differential Equations
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: Permission of Instructor
Units: 3-0-9
______
Topics vary from year to year.
Information: R. B. Melrose

18.152 Introduction to Partial Differential Equations
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with18.1521)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.152
______
Introduces three main types of partial differential equations: diffusion, elliptic, and hyperbolic. Includes mathematical tools, real-world examples and applications, such as the Black-Scholes equation, the European options problem, water waves, scalar conservation laws, first order equations and traffic problems.
J. Speck

18.1521 Introduction to Partial Differential Equations
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with18.152)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
______
Introduces three main types of partial differential equations: diffusion, elliptic, and hyperbolic. Includes mathematical tools, real-world examples and applications, such as the Black-Scholes equation, the European options problem, water waves, scalar conservation laws, first order equations and traffic problems. Students in Course 18 must register for the undergraduate version, 18.152.
J. Speck

18.155 Differential Analysis I
______

Graduate (Fall)
Prereq: 18.102 or 18.103
Units: 3-0-9
URL: http://math.mit.edu/classes/18.155
Lecture: TR11-12.30 (2-135)
______
R. B. Melrose
No required or recommended textbooks

18.156 Differential Analysis II
______

Graduate (Spring)
Prereq: 18.155
Units: 3-0-9
URL: http://math.mit.edu/classes/18.156
______
Fall: Review of Lebesgue integration. Lp spaces. Distributions. Fourier transform. Sobolev spaces. Spectral theorem, discrete and continuous spectrum. Homogeneous distributions. Fundamental solutions for elliptic, hyperbolic and parabolic differential operators. Spring: Variable coefficient elliptic, parabolic and hyperbolic partial differential equations. 18.112 recommended for 18.155.
Fall:R. B. Melrose
Spring:S. Dyatlov

18.157 Introduction to Microlocal Analysis
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 18.155
Units: 3-0-9
URL: http://math.mit.edu/classes/18.157
______
The semi-classical theory of partial differential equations. Discussion of Pseudodifferential operators, Fourier integral operators, asymptotic solutions of partial differential equations, and the spectral theory of Schroedinger operators from the semi-classical perspective. Heavy emphasis placed on the symplectic geometric underpinnings of this subject.
V. W. Guillemin

18.158 Topics in Differential Equations
______

Graduate (Spring) Can be repeated for credit
Prereq: 18.157
Units: 3-0-9
URL: http://math.mit.edu/classes/18.158/
______
Topics vary from year to year.
G. Staffilani

18.175 Theory of Probability
______

Graduate (Fall)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q
Units: 3-0-9
URL: http://math.mit.edu/classes/18.175
Lecture: TR2.30-4 (2-131)
______
Sums of independent random variables, central limit phenomena, infinitely divisible laws, Levy processes, Brownian motion, conditioning, and martingales. Prior exposure to probability (e.g., 18.600) recommended.
S. Sheffield
No textbook information available

18.176 Stochastic Calculus
______

Graduate (Spring)
Prereq: 18.175
Units: 3-0-9
______
Introduction to stochastic processes with an emphasis on their relationship to other branches of analysis, especially partial differential equations. Topics include Brownian motion, continuous parameter martingales, Ito's theory of stochastic differential equations, Levy processes, and may also address Malliavin''s calculus. Students should have familiarity with Lebesgue integration and its application to probability, as well knowledge of the Fourier transform and other basic tools of analysis.
D. W. Stroock

18.177 Topics in Stochastic Processes
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 18.175
Units: 3-0-9
URL: http://math.mit.edu/classes/18.177
Lecture: TR9.30-11 (2-142)
______
Topics vary from year to year.
Fall:V. Gorin
Spring:E. Mossel
No required or recommended textbooks

18.199 Graduate Analysis Seminar
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
Studies original papers in differential analysis and differential equations. Intended for first- and second-year graduate students. Permission must be secured in advance.
V. W. Guillemin

Discrete Applied Mathematics

18.200 Principles of Discrete Applied Mathematics
______

Undergrad (Fall)
Prereq: Calculus II (GIR)
Units: 4-0-11
Credit cannot also be received for18.200A
Lecture: MWF12 (2-190) Recitation: R10 (2-132) or R12 (2-143) or R1 (2-143) or R3 (2-142)
______
Study of illustrative topics in discrete applied mathematics, including sorting algorithms, probability theory, information theory, coding theory, secret codes, generating functions, and linear programming. Instruction and practice in written communication provided. Enrollment limited.
M. X. Goemans
No required or recommended textbooks

18.200A Principles of Discrete Applied Mathematics
______

Undergrad (Spring)
Prereq: Calculus II (GIR)
Units: 3-0-9
Credit cannot also be received for18.200
______
Study of illustrative topics in discrete applied mathematics, including sorting algorithms, probability theory, information theory, coding theory, secret codes, generating functions, and linear programming.
P. W. Shor

18.204 Undergraduate Seminar in Discrete Mathematics
______

Undergrad (Fall, Spring)
Prereq: 18.200 or 18.062; 18.06, 18.700, or 18.701; or permission of instructor
Units: 3-0-9
Lecture: MWF2 (2-132, 2-151)
______
Seminar in combinatorics, graph theory, and discrete mathematics in general. Participants read and present papers from recent mathematics literature. Instruction and practice in written and oral communication provided. Enrollment limited.
Fall:T. McConville
Spring:Y. Wang
No required or recommended textbooks

18.211 Combinatorial Analysis
______

Undergrad (Fall)
Prereq: Calculus II (GIR); 18.06, 18.700, or 18.701
Units: 3-0-9
Lecture: MWF1 (2-132) +final
______
Combinatorial problems and methods for their solution. Enumeration, generating functions, recurrence relations, construction of bijections. Introduction to graph theory. Prior experience with abstraction and proofs is helpful.
M. Rahman
Textbooks (Fall 2016)

18.212 Algebraic Combinatorics
______

Undergrad (Spring)
Prereq: 18.701 or 18.703
Units: 3-0-9
______
Applications of algebra to combinatorics. Topics include walks in graphs, the Radon transform, groups acting on posets, Young tableaux, electrical networks.
T. McConville

18.217 Combinatorial Theory
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
Lecture: MWF11 (2-131)
______
Content varies from year to year.
R. P. Stanley
Textbooks (Fall 2016)

18.218 Topics in Combinatorics
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
Topics vary from year to year.
A. Postnikov

18.219 Seminar in Combinatorics
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
Content varies from year to year. Readings from current research papers in combinatorics. Topics to be chosen and presented by the class.
J. Fox

Continuous Applied Mathematics

18.300 Principles of Continuum Applied Mathematics
______

Undergrad (Spring)
Prereq: Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9
______
Covers fundamental concepts in continuous applied mathematics. Applications from traffic flow, fluids, elasticity, granular flows, etc. Also covers continuum limit; conservation laws, quasi-equilibrium; kinematic waves; characteristics, simple waves, shocks; diffusion (linear and nonlinear); numerical solution of wave equations; finite differences, consistency, stability; discrete and fast Fourier transforms; spectral methods; transforms and series (Fourier, Laplace). Additional topics may include sonic booms, Mach cone, caustics, lattices, dispersion and group velocity. Uses MATLAB computing environment.
L. Faria

18.303 Linear Partial Differential Equations: Analysis and Numerics
______

Undergrad (Fall)
Prereq: 18.06 or 18.700
Units: 3-0-9
URL: http://math.mit.edu/classes/18.303
Lecture: MWF2 (4-159)
______
Provides students with the basic analytical and computational tools of linear partial differential equations (PDEs) for practical applications in science and engineering, including heat/diffusion, wave, and Poisson equations. Analytics emphasize the viewpoint of linear algebra and the analogy with finite matrix problems. Studies operator adjoints and eigenproblems, series solutions, Green's functions, and separation of variables. Numerics focus on finite-difference and finite-element techniques to reduce PDEs to matrix problems, including stability and convergence analysis and implicit/explicit timestepping. Some programming required for homework and final project.
S. G. Johnson
Textbooks (Fall 2016)

18.305 Advanced Analytic Methods in Science and Engineering
______

Graduate (Fall)
Prereq: 18.04, 18.075, or 18.112
Units: 3-0-9
URL: http://math.mit.edu/18.305/
Lecture: MWF12 (2-135)
______
Covers expansion around singular points: the WKB method on ordinary and partial differential equations; the method of stationary phase and the saddle point method; the two-scale method and the method of renormalized perturbation; singular perturbation and boundary-layer techniques; WKB method on partial differential equations.
H. Cheng
Textbooks (Fall 2016)

18.306 Advanced Partial Differential Equations with Applications
______

Graduate (Spring)
Prereq: 18.03 or 18.034; 18.04, 18.075, or 18.112
Units: 3-0-9
URL: http://math.mit.edu/classes/18.306
______
Concepts and techniques for partial differential equations, especially nonlinear. Diffusion, dispersion and other phenomena. Initial and boundary value problems. Normal mode analysis, Green's functions, and transforms. Conservation laws, kinematic waves, hyperbolic equations, characteristics shocks, simple waves. Geometrical optics, caustics. Free-boundary problems. Dimensional analysis. Singular perturbation, boundary layers, homogenization. Variational methods. Solitons. Applications from fluid dynamics, materials science, optics, traffic flow, etc.
R. R. Rosales

18.327 Topics in Applied Mathematics
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/1.130/
______
Topics vary from year to year.
L. Demanet

18.330 Introduction to Numerical Analysis
______

Undergrad (Spring)
Prereq: Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9
URL: http://math.mit.edu/classes/18.330/
______
Basic techniques for the efficient numerical solution of problems in science and engineering. Root finding, interpolation, approximation of functions, integration, differential equations, direct and iterative methods in linear algebra. Knowledge of programming in Fortran, C, or MATLAB helpful.
H. Reid

18.335[J] Introduction to Numerical Methods
______

Graduate (Spring)
(Same subject as6.337[J])
Prereq: 18.03 or 18.034; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.335
______
Advanced introduction to numerical linear algebra and other central algorithms of scientific computation. Topics include direct and iterative methods for linear systems, eigenvalue and QR/SVD factorizations, stability and accuracy, floating-point arithmetic, sparse matrices, preconditioning, and the memory considerations underlying modern linear-algebra software. Techniques for local and global nonlinear optimization, including quasi-Newton methods, trust regions, branch-and-bound, and multistart algorithms. Chebyshev approximations, numerical integration, and FFTs. A modern high-level language, Julia, is introduced for problem sets.
W. Shin

18.336[J] Fast Methods for Partial Differential and Integral Equations
______

Graduate (Fall)
(Same subject as6.335[J])
Prereq: 6.336, 16.920, 18.085, 18.335, or permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.336
Lecture: MW9.30-11 (2-146)
______
Unified introduction to the theory and practice of modern, near linear-time, numerical methods for large-scale partial-differential and integral equations. Topics include preconditioned iterative methods; generalized Fast Fourier Transform and other butterfly-based methods; multiresolution approaches, such as multigrid algorithms and hierarchical low-rank matrix decompositions; and low and high frequency Fast Multipole Methods. Example applications include aircraft design, cardiovascular system modeling, electronic structure computation, and tomographic imaging.
C. Perez
No required or recommended textbooks

18.337[J] Parallel Computing
______

Graduate (Fall)
(Same subject as6.338[J])
Prereq: 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://beowulf.csail.mit.edu/18.337/index.html
Lecture: MW2-3.30 (4-237)
______
Interdisciplinary introduction to computing with Julia. Covers scientific computing and data analysis problems. Combines knowledge from computer science and computational science illustrating Julia's new approach to scientific computing. Sample scientific computing topics include dense and sparse linear algebra, Fourier transforms, data handling, and N-body problems. Provides direct experience with programming traditional-style supercomputing as well as working with modern cloud computing stacks.
A. Edelman
No textbook information available

18.338 Eigenvalues of Random Matrices
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.701 or permission of instructor
Units: 3-0-9
URL: http://www.mit.edu/~18.338/
______
Covers the modern main results of random matrix theory as it is currently applied in engineering and science. Topics include matrix calculus for finite and infinite matrices (e.g., Wigner's semi-circle and Marcenko-Pastur laws), free probability, random graphs, combinatorial methods, matrix statistics, stochastic operators, passage to the continuum limit, moment methods, and compressed sensing. Knowledge of MATLAB hepful, but not required.
A. Edelman

18.352[J] Nonlinear Dynamics: The Natural Environment
______

Undergrad (Spring)
(Same subject as12.009[J])
Prereq: Physics I (GIR), Calculus II (GIR);Coreq: 18.03
Units: 3-0-9
______
Analyzes cooperative processes that shape the natural environment, now and in the geologic past. Emphasizes the development of theoretical models that relate the physical and biological worlds, the comparison of theory to observational data, and associated mathematical methods. Topics include carbon cycle dynamics; ecosystem structure, stability and complexity; mass extinctions; biosphere-geosphere coevolution; and climate change. Employs techniques such as stability analysis; scaling; null model construction; time series and network analysis.
D. H. Rothman

18.353[J] Nonlinear Dynamics: Chaos
______

Undergrad (Fall)
(Same subject as 2.050[J],12.006[J])
Prereq: 18.03 or 18.034; Physics II (GIR)
Units: 3-0-9
Lecture: TR1-2.30 (2-105)
______
Introduction to nonlinear dynamics and chaos in dissipative systems. Forced and parametric oscillators. Phase space. Periodic, quasiperiodic, and aperiodic flows. Sensitivity to initial conditions and strange attractors. Lorenz attractor. Period doubling, intermittency, and quasiperiodicity. Scaling and universality. Analysis of experimental data: Fourier transforms, Poincare sections, fractal dimension, and Lyapunov exponents. Applications to mechanical systems, fluid dynamics, physics, geophysics, and chemistry. See 12.207J/18.354J for Nonlinear Dynamics: Continuum Systems.
P-T. Brun
Textbooks (Fall 2016)

18.354[J] Nonlinear Dynamics: Continuum Systems
______

Undergrad (Spring)
(Same subject as1.062[J],12.207[J])
(Subject meets with18.3541)
Prereq: 18.03 or 18.034; Physics II (GIR)
Units: 3-0-9
URL: http://math.mit.edu/classes/18.354/
______
General mathematical principles of continuum systems. From microscopic to macroscopic descriptions in the form of linear or nonlinear (partial) differential equations. Exact solutions, dimensional analysis, calculus of variations and singular perturbation methods. Stability, waves and pattern formation in continuum systems. Subject matter illustrated using natural fluid and solid systems found, for example, in geophysics and biology.
P. Pearce

18.3541 Nonlinear Dynamics: Continuum Systems
______

Graduate (Spring)
(Subject meets with1.062[J],12.207[J],18.354[J])
Prereq: 18.03 or 18.034; Physics II (GIR)
Units: 3-0-9
______
General mathematical principles of continuum systems. From microscopic to macroscopic descriptions in the form of linear or nonlinear (partial) differential equations. Exact solutions, dimensional analysis, calculus of variations and singular perturbation methods. Stability, waves and pattern formation in continuum systems. Subject matter illustrated using natural fluid and solid systems found, for example, in geophysics and biology. Students in Courses 1, 12, and 18 must register for undergraduate version, 18.354.
P. Pearce

18.355 Fluid Mechanics
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 18.354, 2.25, or 12.800
Units: 3-0-9
Lecture: MW2-3.30 (2-135)
______
Topics include the development of Navier-Stokes equations, inviscid flows, boundary layers, lubrication theory, Stokes flows, and surface tension. Fundamental concepts illustrated through problems drawn from a variety of areas, including geophysics, biology, and the dynamics of sport. Particular emphasis on the interplay between dimensional analysis, scaling arguments, and theory. Includes classroom and laboratory demonstrations.
J. W. Bush
No required or recommended textbooks

18.357 Interfacial Phenomena
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.354, 18.355, 12.800, 2.25, or permission of instructor
Units: 3-0-9
______
Fluid systems dominated by the influence of interfacial tension. Elucidates the roles of curvature pressure and Marangoni stress in a variety of hydrodynamic settings. Particular attention to drops and bubbles, soap films and minimal surfaces, wetting phenomena, water-repellency, surfactants, Marangoni flows, capillary origami and contact line dynamics. Theoretical developments are accompanied by classroom demonstrations. Highlights the role of surface tension in biology.
J. W. Bush

18.358[J] Nonlinear Dynamics and Turbulence
(New)
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as1.686[J])
(Subject meets with1.068)
Prereq: 18.355 or permission of instructor
Units: 3-0-9
______
Reviews theoretical notions of nonlinear dynamics, instabilities, and waves with applications in fluid dynamics. Discusses hydrodynamic instabilities leading to flow destabilization and transition to turbulence. Focuses on physical turbulence and mixing from homogenous isotropic turbulence. Also covers topics such as rotating and stratified flows as they arise in the environment, wave-turbulence, and point source turbulent flows. Students taking graduate version complete additional assignments.
L. Bourouiba

18.369 Mathematical Methods in Nanophotonics
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.305 or permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.369
______
High-level approaches to understanding complex optical media, structured on the scale of the wavelength, that are not generally analytically soluable. The basis for understanding optical phenomena such as photonic crystals and band gaps, anomalous diffraction, mechanisms for optical confinement, optical fibers (new and old), nonlinearities, and integrated optical devices. Methods covered include linear algebra and eigensystems for Maxwell's equations, symmetry groups and representation theory, Bloch's theorem, numerical eigensolver methods, time and frequency-domain computation, perturbation theory, and coupled-mode theories.
S. G. Johnson

18.376[J] Wave Propagation
______

Graduate (Spring)
(Same subject as1.138[J],2.062[J])
Prereq: 2.003, 18.075
Units: 3-0-9
URL: http://math.mit.edu/classes/18.376/
______
Theoretical concepts and analysis of wave problems in science and engineering with examples chosen from elasticity, acoustics, geophysics, hydrodynamics, blood flow, nondestructive evaluation, and other applications. Progressive waves, group velocity and dispersion, energy density and transport. Reflection, refraction and transmission of plane waves by an interface. Mode conversion in elastic waves. Rayleigh waves. Waves due to a moving load. Scattering by a two-dimensional obstacle. Reciprocity theorems. Parabolic approximation. Waves on the sea surface. Capillary-gravity waves. Wave resistance. Radiation of surface waves. Internal waves in stratified fluids. Waves in rotating media. Waves in random media.
T. R. Akylas, R. R. Rosales

18.377[J] Nonlinear Dynamics and Waves
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as1.685[J],2.034[J])
Prereq: Permission of instructor
Units: 3-0-9
______
A unified treatment of nonlinear oscillations and wave phenomena with applications to mechanical, optical, geophysical, fluid, electrical and flow-structure interaction problems. Nonlinear free and forced vibrations; nonlinear resonances; self-excited oscillations; lock-in phenomena. Nonlinear dispersive and nondispersive waves; resonant wave interactions; propagation of wave pulses and nonlinear Schrodinger equation. Nonlinear long waves and breaking; theory of characteristics; the Korteweg-de Vries equation; solitons and solitary wave interactions. Stability of shear flows. Some topics and applications may vary from year to year.
T. R. Akylas, R. R. Rosales

18.384 Undergraduate Seminar in Physical Mathematics
______

Undergrad (Fall)
Prereq: 18.300, 18.353, 18.354, or permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.384
Lecture: TR11-12.30 (2-151)
______
Covers the mathematical modeling of physical systems, with emphasis on the reading and presentation of papers. Addresses a broad range of topics, with particular focus on macroscopic physics and continuum systems: fluid dynamics, solid mechanics, and biophysics. Instruction and practice in written and oral communication provided. Enrollment limited.
L. Faria
No required or recommended textbooks

18.385[J] Nonlinear Dynamics and Chaos
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as2.036[J])
Prereq: 18.03 or 18.034
Units: 3-0-9
URL: http://math.mit.edu/classes/18.385
Lecture: TR11-12.30 (2-136)
______
Introduction to the theory of nonlinear dynamical systems with applications from science and engineering. Local and global existence of solutions, dependence on initial data and parameters. Elementary bifurcations, normal forms. Phase plane, limit cycles, relaxation oscillations, Poincare-Bendixson theory. Floquet theory. Poincare maps. Averaging. Near-equilibrium dynamics. Synchronization. Introduction to chaos. Universality. Strange attractors. Lorenz and Rossler systems. Hamiltonian dynamics and KAM theory. Uses MATLAB computing environment.
R. R. Rosales
Textbooks (Fall 2016)

18.395 Group Theory with Applications to Physics
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 8.321
Units: 3-0-9
______
Selection of topics from the theory of finite groups, Lie groups, and group representations, motivated by quantum mechanics and particle physics. 8.322 and 8.323 helpful.
D. Z. Freedman

18.396[J] Supersymmetric Quantum Field Theories
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
(Same subject as8.831[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Topics selected from the following: SUSY algebras and their particle representations; Weyl and Majorana spinors; Lagrangians of basic four-dimensional SUSY theories, both rigid SUSY and supergravity; supermultiplets of fields and superspace methods; renormalization properties, and the non-renormalization theorem; spontaneous breakdown of SUSY; and phenomenological SUSY theories. Some prior knowledge of Noether's theorem, derivation and use of Feynman rules, l-loop renormalization, and gauge theories is essential.
D. Z. Freedman

Theoretical Computer Science

18.400[J] Automata, Computability, and Complexity
______

Undergrad (Spring)
(Same subject as6.045[J])
Prereq: 6.042
Units: 4-0-8
URL: http://math.mit.edu/classes/18.400
______
Provides an introduction to some of the central ideas of theoretical computer science, including circuits, finite automata, Turing machines and computability, efficient algorithms and reducibility, the P versus NP problem, NP-completeness, the power of randomness, cryptography, computational learning theory, and quantum computing. Examines the classes of problems that can and cannot be solved in various computational models.
S. Aaronson

18.404 Theory of Computation
______

Undergrad (Fall)
(Subject meets with6.840[J],18.4041[J])
Prereq: 18.200 or 18.062J
Units: 4-0-8
URL: http://math.mit.edu/classes/18.404
1st mtg Sept 8 at 2.30. Room 54-100. Lecture: TR2.30-4 (2-190) Recitation: F12 (2-143) or F1 (2-139) or F2 (2-139) +final
______
A more extensive and theoretical treatment of the material in 6.045J/18.400J, emphasizing computability and computational complexity theory. Regular and context-free languages. Decidable and undecidable problems, reducibility, recursive function theory. Time and space measures on computation, completeness, hierarchy theorems, inherently complex problems, oracles, probabilistic computation, and interactive proof systems.
M. Sipser
Textbooks (Fall 2016)

18.4041[J] Theory of Computation
______

Graduate (Fall)
(Same subject as6.840[J])
(Subject meets with18.404)
Prereq: 18.200 or 18.062J
Units: 4-0-8
1st mtg Sept 8 at 2.30. Room 54-100. Lecture: TR2.30-4 (2-190) Recitation: F12 (2-143) or F1 (2-139) or F2 (2-139) +final
______
A more extensive and theoretical treatment of the material in 6.045J/18.400J, emphasizing computability and computational complexity theory. Regular and context-free languages. Decidable and undecidable problems, reducibility, recursive function theory. Time and space measures on computation, completeness, hierarchy theorems, inherently complex problems, oracles, probabilistic computation, and interactive proof systems. Students in Course 18 must register for the undergraduate version, 18.404.
M. Sipser
Textbooks (Fall 2016)

18.405[J] Advanced Complexity Theory
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as6.841[J])
Prereq: 18.404
Units: 3-0-9
______
Current research topics in computational complexity theory. Nondeterministic, alternating, probabilistic, and parallel computation models. Boolean circuits. Complexity classes and complete sets. The polynomial-time hierarchy. Interactive proof systems. Relativization. Definitions of randomness. Pseudo-randomness and derandomizations. Interactive proof systems and probabilistically checkable proofs.
D. Moshkovitz

18.408 Topics in Theoretical Computer Science
______

Not offered academic year 2017-2018Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
Lecture: F9-12 (4-163)
______
Study of areas of current interest in theoretical computer science. Topics vary from term to term.
Information: M. X. Goemans
No required or recommended textbooks

18.410[J] Design and Analysis of Algorithms
______

Undergrad (Fall, Spring)
(Same subject as6.046[J])
Prereq: 6.006
Units: 4-0-8
URL: http://math.mit.edu/classes/18.410
Lecture: TR11-12.30 (32-123) Recitation: F10 (4-159) or F11 (4-159, 4-149, 36-156) or F12 (36-156, 4-159) or F1 (4-159, 4-149) or F2 (35-308) or F3 (35-308) +final
______
Techniques for the design and analysis of efficient algorithms, emphasizing methods useful in practice. Topics include sorting; search trees, heaps, and hashing; divide-and-conquer; dynamic programming; greedy algorithms; amortized analysis; graph algorithms; and shortest paths. Advanced topics may include network flow; computational geometry; number-theoretic algorithms; polynomial and matrix calculations; caching; and parallel computing.
E. Demaine, M. Goemans
Textbooks (Fall 2016)

18.415[J] Advanced Algorithms
______

Graduate (Fall)
(Same subject as6.854[J])
Prereq: 6.041B, 6.042, or 18.600; 6.046
Units: 5-0-7
URL: http://theory.lcs.mit.edu/classes/6.854/
Lecture: MWF2.30-4 (32-141)
______
First-year graduate subject in algorithms. Emphasizes fundamental algorithms and advanced methods of algorithmic design, analysis, and implementation. Surveys a variety of computational models and the algorithms for them. Data structures, network flows, linear programming, computational geometry, approximation algorithms, online algorithms, parallel algorithms, external memory, streaming algorithms.
A. Moitra, D. R. Karger
No required or recommended textbooks

18.416[J] Randomized Algorithms
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as6.856[J])
Prereq: 6.854J, 6.041B or 6.042J
Units: 5-0-7
______
Studies how randomization can be used to make algorithms simpler and more efficient via random sampling, random selection of witnesses, symmetry breaking, and Markov chains. Models of randomized computation. Data structures: hash tables, and skip lists. Graph algorithms: minimum spanning trees, shortest paths, and minimum cuts. Geometric algorithms: convex hulls, linear programming in fixed or arbitrary dimension. Approximate counting; parallel algorithms; online algorithms; derandomization techniques; and tools for probabilistic analysis of algorithms.
D. R. Karger

18.417 Introduction to Computational Molecular Biology
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 6.01, 6.006, or permission of instructor
Units: 3-0-9
URL: http://www-math.mit.edu/18.417/
______
Introduces the basic computational methods used to model and predict the structure of biomolecules (proteins, DNA, RNA). Covers classical techniques in the field (molecular dynamics, Monte Carlo, dynamic programming) to more recent advances in analyzing and predicting RNA and protein structure, ranging from Hidden Markov Models and 3-D lattice models to attribute Grammars and tree Grammars.
Information: B. Berger

18.418 Topics in Computational Molecular Biology
______

Graduate (Spring) Can be repeated for credit
Prereq: 18.417, 6.047, or permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.418
______
Covers current research topics in computational molecular biology. Recent research papers presented from leading conferences such as the SIGACT International Conference on Computational Molecular Biology (RECOMB). Topics include original research (both theoretical and experimental) in comparative genomics, sequence and structure analysis, molecular evolution, proteomics, gene expression, transcriptional regulation, and biological networks. Recent research by course participants also covered. Participants will be expected to present either group or individual projects to the class.
B. Berger

18.424 Seminar in Information Theory
______

Undergrad (Fall)
Prereq: 18.05, 18.600, or 6.041B; 18.06, 18.700, or 18.701
Units: 3-0-9
Lecture: TR11-12.30 (2-142)
______
Considers various topics in information theory, including data compression, Shannon's Theorems, and error-correcting codes. Students present and discuss the subject matter. Instruction and practice in written and oral communication provided. Enrollment limited.
P. W. Shor
Textbooks (Fall 2016)

18.425[J] Cryptography and Cryptanalysis
______

Graduate (Spring)
(Same subject as6.875[J])
Prereq: 6.046J
Units: 3-0-9
______
A rigorous introduction to modern cryptography. Emphasis on the fundamental cryptographic primitives of public-key encryption, digital signatures, pseudo-random number generation, and basic protocols and their computational complexity requirements.
S. Goldwasser, S. Micali

18.434 Seminar in Theoretical Computer Science
______

Undergrad (Spring)
Prereq: 18.410
Units: 3-0-9
URL: http://math.mit.edu/classes/18.434
______
Topics vary from year to year. Students present and discuss the subject matter. Instruction and practice in written and oral communication provided. Enrollment limited.
Information: P. Shor

18.435[J] Quantum Computation
______

Graduate (Fall)
(Same subject as2.111[J],8.370[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (4-370) +final
______
Provides an introduction to the theory and practice of quantum computation. Topics covered: physics of information processing; quantum algorithms including the factoring algorithm and Grover's search algorithm; quantum error correction; quantum communication and cryptography. Knowledge of quantum mechanics helpful but not required.
I. Chuang, E. Farhi, S. Lloyd, P. Shor
Textbooks (Fall 2016)

18.436[J] Quantum Information Science
______

Graduate (Spring)
(Same subject as6.443[J],8.371[J])
Prereq: 18.435
Units: 3-0-9
______
Examines quantum computation and quantum information. Topics include quantum circuits, the quantum Fourier transform and search algorithms, the quantum operations formalism, quantum error correction, Calderbank-Shor-Steane and stabilizer codes, fault tolerant quantum computation, quantum data compression, quantum entanglement, capacity of quantum channels, and quantum cryptography and the proof of its security. Prior knowledge of quantum mechanics required.
I. Chuang

18.437[J] Distributed Algorithms
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as6.852[J])
Prereq: 6.046
Units: 3-0-9
URL: http://theory.csail.mit.edu/classes/6.852/
Subject Cancelled Subject Cancelled
______
Design and analysis of concurrent algorithms, emphasizing those suitable for use in distributed networks. Process synchronization, allocation of computational resources, distributed consensus, distributed graph algorithms, election of a leader in a network, distributed termination, deadlock detection, concurrency control, communication, and clock synchronization. Special consideration given to issues of efficiency and fault tolerance. Formal models and proof methods for distributed computation.
N. A. Lynch

18.453 Combinatorial Optimization
______

Not offered academic year 2017-2018Undergrad (Spring)
(Subject meets with18.4531)
Prereq: 18.06, 18.700, or 18.701
Units: 3-0-9
______
Thorough treatment of linear programming and combinatorial optimization. Topics include matching theory, network flow, matroid optimization, and how to deal with NP-hard optimization problems. Prior exposure to discrete mathematics (such as 18.200) helpful.
M. X. Goemans

18.4531 Combinatorial Optimization
______

Not offered academic year 2017-2018Graduate (Spring)
(Subject meets with18.453)
Prereq: 18.06, 18.700, or 18.701
Units: 3-0-9
______
Thorough treatment of linear programming and combinatorial optimization. Topics include matching theory, network flow, matroid optimization, and how to deal with NP-hard optimization problems. Prior exposure to discrete mathematics (such as 18.200) helpful. Students in Course 18 must register for the undergraduate version, 18.453.
M. X. Goemans

18.455 Advanced Combinatorial Optimization
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.453 or permission of instructor
Units: 3-0-9
______
Advanced treatment of combinatorial optimization with an emphasis on combinatorial aspects. Non-bipartite matchings, submodular functions, matroid intersection/union, matroid matching, submodular flows, multicommodity flows, packing and connectivity problems, and other recent developments.
M. X. Goemans


left arrow|18.01-18.499|18.50-18.THG|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 18: Mathematics
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Course 18: Mathematics
Fall 2016


Logic

18.504 Seminar in Logic
______

Not offered academic year 2017-2018Undergrad (Spring)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.510, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.504
______
Students present and discuss the subject matter taken from current journals or books. Topics vary from year to year. Instruction and practice in written and oral communication provided. Enrollment limited.
H. Cohn

18.510 Introduction to Mathematical Logic and Set Theory
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: None
Units: 3-0-9
URL: http://math.mit.edu/classes/18.510
______
Propositional and predicate logic. Zermelo-Fraenkel set theory. Ordinals and cardinals. Axiom of choice and transfinite induction. Elementary model theory: completeness, compactness, and Lowenheim-Skolem theorems. Godel's incompleteness theorem.
H. Cohn

18.515 Mathematical Logic
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.515
______
More rigorous treatment of basic mathematical logic, Godel's theorems, and Zermelo-Fraenkel set theory. First-order logic. Models and satisfaction. Deduction and proof. Soundness and completeness. Compactness and its consequences. Quantifier elimination. Recursive sets and functions. Incompleteness and undecidability. Ordinals and cardinals. Set-theoretic formalization of mathematics.
Information: B. Poonen

Probability and Statistics

18.600 Probability and Random Variables
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR)
Units: 3-0-9
Lecture: MWF10 (54-100) +final
______
Probability spaces, random variables, distribution functions. Binomial, geometric, hypergeometric, Poisson distributions. Uniform, exponential, normal, gamma and beta distributions. Conditional probability, Bayes theorem, joint distributions. Chebyshev inequality, law of large numbers, and central limit theorem. Credit cannot also be received for 6.041A or 6.041B.
Fall:E. Mossel
Spring:S. Sheffield
Textbooks (Fall 2016)

18.615 Introduction to Stochastic Processes
______

Graduate (Spring)
Prereq: 18.600 or 6.041B
Units: 3-0-9
______
Basics of stochastic processes. Markov chains, Poisson processes, random walks, birth and death processes, Brownian motion.
A. Bufetov

18.642 Topics in Mathematics with Applications in Finance
______

Undergrad (Fall)
Prereq: 18.03; 18.06; 18.05 or 18.600
Units: 3-0-9
Lecture: TR2.30-4 (4-163)
______
Introduction to mathematical concepts and techniques used in finance. Lectures focusing on linear algebra, probability, statistics, stochastic processes, and numerical methods are interspersed with lectures by financial sector professionals illustrating the corresponding application in the industry. Prior knowledge of economics or finance helpful but not required.
P. Kempthorne, V. Strela, J. Xia
Textbooks (Fall 2016)

18.650 Statistics for Applications
______

Undergrad (Fall, Spring)
(Subject meets with18.6501)
Prereq: 18.600 or 6.041B
Units: 3-0-9
Lecture: TR1-2.30 (2-190) +final
______
A broad treatment of statistics, concentrating on specific statistical techniques used in science and industry. Topics: hypothesis testing and estimation. Confidence intervals, chi-square tests, nonparametric statistics, analysis of variance, regression, correlation, decision theory, and Bayesian statistics.
Fall:P. Rigollet
Spring:P. Kempthorne
No required or recommended textbooks

18.6501 Statistics for Applications
______

Graduate (Fall, Spring)
(Subject meets with18.650)
Prereq: 18.600 or 6.041B
Units: 3-0-9
Lecture: TR1-2.30 (2-190) +final
______
A broad treatment of statistics, concentrating on specific statistical techniques used in science and industry. Topics: hypothesis testing and estimation. Confidence intervals, chi-square tests, nonparametric statistics, analysis of variance, regression, correlation, decision theory, and Bayesian statistics. Students in Course 18 must register for the undergraduate version, 18.650.
Fall:P. Rigollet
Spring:P. Kempthorne
No required or recommended textbooks

18.655 Mathematical Statistics
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Decision theory, estimation, confidence intervals, hypothesis testing. Introduces large sample theory. Asymptotic efficiency of estimates. Exponential families. Sequential analysis.
P. Kempthorne

18.657 Topics in Statistics
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
Topics vary from term to term.
P. Rigollet

For additional related subjects in Statistics, see:

Civil and Environmental Engineering: 1.151, 1.155,1.202J, 1.203J, 1.205J

Electrical Engineering and Computer Science: 6.041,6.231, 6.245, 6.262, 6.431, 6.432, and 6.435

Management: 15.034, 15.061, 15.065, 15.070, 15.075, 15.076, 15.098, and 15.306

Mathematics: 18.05, 18.175, 18.176, 18.177, 18.600, 18.615, 18.642, 18.650, 18.655, and 18.657

See also: 2.061, 2.830, 5.70, 5.72, 7.02, 8.044, 8.08,10.816, 11.220, 11.221, 16.322, 17.872, 17.874, 22.38, HST.191, and MAS.622J.

Algebra and Number Theory

18.700 Linear Algebra
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR)
Units: 3-0-9
Credit cannot also be received for18.06
URL: http://math.mit.edu/classes/18.700
Lecture: MWF1 (2-105) +final
______
Vector spaces, systems of linear equations, bases, linear independence, matrices, determinants, eigenvalues, inner products, quadratic forms, and canonical forms of matrices. More emphasis on theory and proofs than in 18.06.
C. Xu
Textbooks (Fall 2016)

18.701 Algebra I
______

Undergrad (Fall)
Prereq: 18.100A, 18.100B, 18.100P, 18.100Q, or permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.701
Lecture: MWF11 (2-190)
______
M. Artin
Textbooks (Fall 2016)

18.702 Algebra II
______

Undergrad (Spring)
Prereq: 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.702
______
More extensive and theoretical than the 18.700-18.703 sequence. Experience with proofs necessary. First term: group theory, geometry, and linear algebra. Second term: group representations, rings, ideals, fields, polynomial rings, modules, factorization, integers in quadratic number fields, field extensions, Galois theory.
M. Artin

18.703 Modern Algebra
______

Undergrad (Spring)
Prereq: Calculus II (GIR)
Units: 3-0-9
URL: http://math.mit.edu/classes/18.703/
______
Focuses on traditional algebra topics that have found greatest application in science and engineering as well as in mathematics: group theory, emphasizing finite groups; ring theory, including ideals and unique factorization in polynomial and Euclidean rings; field theory, including properties and applications of finite fields. 18.700 and 18.703 together form a standard algebra sequence.
P. I. Etingof

18.704 Seminar in Algebra
______

Undergrad (Spring)
Prereq: 18.701; or 18.06, 18.703; or 18.700, 18.703
Units: 3-0-9
URL: http://math.mit.edu/classes/18.704
______
Topics vary from year to year. Students present and discuss the subject matter. Instruction and practice in written and oral communication provided. Some experience with proofs required. Enrollment limited.
V. G. Kac

18.705 Commutative Algebra
______

Graduate (Fall)
Prereq: 18.702
Units: 3-0-9
URL: http://math.mit.edu/classes/18.705
Lecture: TR11-12.30 (2-132)
______
Exactness, direct limits, tensor products, Cayley-Hamilton theorem, integral dependence, localization, Cohen-Seidenberg theory, Noether normalization, Nullstellensatz, chain conditions, primary decomposition, length, Hilbert functions, dimension theory, completion, Dedekind domains.
A. Negut
Textbooks (Fall 2016)

18.706 Noncommutative Algebra
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 18.705
Units: 3-0-9
URL: http://math.mit.edu/classes/18.706/
______
Topics may include representations of quivers, Wedderburn theory, Morita equivalence, localization and Goldie's theorem, central simple algebras and the Brauer group, maximal orders, representations, polynomial identity rings, invariant theory growth of algebras, Gelfand-Kirillov dimension.
G. Lusztig

18.708 Topics in Algebra
______

Not offered academic year 2017-2018Graduate (Spring) Can be repeated for credit
Prereq: 18.705
Units: 3-0-9
______
Topics vary from year to year.
Information: P. I. Etingof

18.715 Introduction to Representation Theory
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 18.702 or 18.703
Units: 3-0-9
Lecture: TR9.30-11 (4-163)
______
Algebras, representations, Schur's lemma. Representations of SL(2). Representations of finite groups, Maschke's theorem, characters, applications. Induced representations, Burnside's theorem, Mackey formula, Frobenius reciprocity. Representations of quivers.
B. Poonen
No required or recommended textbooks

18.721 Introduction to Algebraic Geometry
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 18.702, 18.901
Units: 3-0-9
URL: http://math.mit.edu/classes/18.721
______
Presents basic examples of complex algebraic varieties, affine and projective algebraic geometry, sheaves, cohomology.
M. Artin

18.725 Algebraic Geometry I
______

Graduate (Fall)
Prereq: None.Coreq: 18.705
Units: 3-0-9
URL: http://math.mit.edu/classes/18.725
Lecture: TR12.30-2 (2-135)
______
Introduces the basic notions and techniques of modern algebraic geometry. Covers fundamental notions and results about algebraic varieties over an algebraically closed field; relations between complex algebraic varieties and complex analytic varieties; and examples with emphasis on algebraic curves and surfaces. Introduction to the language of schemes and properties of morphisms. Knowledge of elementary algebraic topology, elementary differential geometry recommended, but not required.
A. Pixton
No required or recommended textbooks

18.726 Algebraic Geometry II
______

Graduate (Spring)
Prereq: 18.725
Units: 3-0-9
URL: http://math.mit.edu/classes/18.726
______
Continuation of the introduction to algebraic geometry given in 18.725. More advanced properties of the varieties and morphisms of schemes, as well as sheaf cohomology.
D. Maulik

18.727 Topics in Algebraic Geometry
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: 18.725
Units: 3-0-9
URL: http://math.mit.edu/classes/18.727
______
Topics vary from year to year.
Information: D. A. Vogan

18.737 Algebraic Groups
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 18.705
Units: 3-0-9
URL: http://math.mit.edu/classes/18.737
Lecture: MW2-3.30 (2-142)
______
Structure of linear algebraic groups over an algebraically closed field, with emphasis on reductive groups. Representations of groups over a finite field using methods from etale cohomology. Some results from algebraic geometry are stated without proof.
G. Lusztig
No required or recommended textbooks

18.745 Introduction to Lie Algebras
______

Graduate (Fall)
Prereq: 18.701 or 18.703
Units: 3-0-9
URL: http://math.mit.edu/classes/18.745
Lecture: TR2.30-4 (2-139)
______
Topics may include structure of finite-dimensional Lie algebras; theorems of Engel and Lie; Cartan subalgebras and regular elements; trace form and Cartan's criterion; Chevalley's conjugacy theorem; classification and construction of semisimple Lie algebras; Weyl group; universal enveloping algebra and the Casimir operator; Weyl's complete reducibility theorem, Levi and Maltsev theorems; Verma modules; classification of irreducible finite-dimensional representations of semisimple Lie algebras; Weyl's character and dimension formulas.
V. G. Kac
No required or recommended textbooks

18.747 Infinite-dimensional Lie Algebras
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.745
Units: 3-0-9
______
Topics vary from year to year.
P. I. Etingof

18.748 Topics in Lie Theory
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
Topics vary from year to year.
P. I. Etingof

18.755 Introduction to Lie Groups
______

Graduate (Fall)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.700 or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.755
Lecture: MWF10 (2-135)
______
A general introduction to manifolds and Lie groups. The role of Lie groups in mathematics and physics. Exponential mapping. Correspondence with Lie algebras. Homogeneous spaces and transformation groups. Adjoint representation. Covering groups. Automorphism groups. Invariant differential forms and cohomology of Lie groups and homogeneous spaces. 18.101 recommended but not required.
S. A. Altug
No required or recommended textbooks

18.757 Representations of Lie Groups
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.745 or 18.755
Units: 3-0-9
URL: http://www-math.mit.edu/~laurajoy/rep.html
______
Covers representations of locally compact groups, with emphasis on compact groups and abelian groups. Includes Peter-Weyl theorem and Cartan-Weyl highest weight theory for compact Lie groups.
L. Rider

18.781 Theory of Numbers
______

Undergrad (Spring)
Prereq: None
Units: 3-0-9
URL: http://math.mit.edu/classes/18.781
______
An elementary introduction to number theory with no algebraic prerequisites. Primes, congruences, quadratic reciprocity, diophantine equations, irrational numbers, continued fractions, partitions.
Information: D. A. Vogan

18.782 Introduction to Arithmetic Geometry
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 18.702
Units: 3-0-9
URL: http://math.mit.edu/classes/18.782
______
Exposes students to arithmetic geometry, motivated by the problem of finding rational points on curves. Includes an introduction to p-adic numbers and some fundamental results from number theory and algebraic geometry, such as the Hasse-Minkowski theorem and the Riemann-Roch theorem for curves. Additional topics may include Mordell's theorem, the Weil conjectures, and Jacobian varieties.
A. Sutherland

18.783 Elliptic Curves
______

Not offered academic year 2017-2018Undergrad (Spring)
(Subject meets with18.7831)
Prereq: None.Coreq: 18.702, 18.703, or permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.783
______
Computationally focused introduction to elliptic curves, with applications to number theory and cryptography. Topics include point-counting, isogenies, pairings, and the theory of complex multiplication, with applications to integer factorization, primality proving, and elliptic curve cryptography. Includes a brief introduction to modular curves and the proof of Fermat's Last Theorem.
A. Sutherland

18.7831 Elliptic Curves
______

Not offered academic year 2017-2018Graduate (Spring)
(Subject meets with18.783)
Prereq: None.Coreq: 18.702, 18.703, or permission of instructor
Units: 3-0-9
______
Computationally focused introduction to elliptic curves, with applications to number theory and cryptography. Topics include point-counting, isogenies, pairings, and the theory of complex multiplication, with applications to integer factorization, primality proving, and elliptic curve cryptography. Includes a brief introduction to modular curves and the proof of Fermat's Last Theorem. Students in Course 18 must register for the undergraduate version, 18.783.
A. Sutherland

18.784 Seminar in Number Theory
______

Undergrad (Fall)
Prereq: 18.06; 18.100A, 18.100B, 18.100P, or 18.100Q
Units: 3-0-9
URL: http://web.mit.edu/abhinavk/www/18.784/index.html
Lecture: MWF11 (2-151)
______
Topics vary from year to year. Students present and discuss the subject matter. Instruction and practice in written and oral communication provided. Enrollment limited.
D. Maulik
Textbooks (Fall 2016)

18.785 Number Theory I
______

Graduate (Fall)
Prereq: None.Coreq: 18.705
Units: 3-0-9
URL: http://math.mit.edu/classes/18.785
Lecture: TR2.30-4 (2-143)
______
Dedekind domains, unique factorization of ideals, splitting of primes. Lattice methods, finiteness of the class group, Dirichlet's unit theorem. Local fields, ramification, discriminants. Zeta and L-functions, analytic class number formula. Adeles and ideles. Statements of class field theory and the Chebotarev density theorem.
A. Sutherland
No required or recommended textbooks

18.786 Number Theory II
______

Graduate (Spring)
Prereq: 18.785
Units: 3-0-9
URL: http://math.mit.edu/classes/18.786
______
Continuation of 18.785. More advanced topics in number theory, such as Galois cohomology, proofs of class field theory, modular forms and automorphic forms, Galois representations, or quadratic forms.
C. C. Tsai

18.787 Topics in Number Theory
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.787/
______
Topics vary from year to year.
B. Poonen

Mathematics Laboratory

18.821 Project Laboratory in Mathematics
______

Undergrad (Fall, Spring) Institute Lab
Prereq: Two mathematics subjects numbered 18.100 or above
Units: 3-6-3
URL: http://math.mit.edu/classes/18.821/
Lecture: MW1,F1-3 (2-147)
______
Guided research in mathematics, employing the scientific method. Students confront puzzling and complex mathematical situations, through the acquisition of data by computer, pencil and paper, or physical experimentation, and attempt to explain them mathematically. Students choose three projects from a large collection of options. Each project results in a laboratory report subject to revision; oral presentation on one or two projects. Projects drawn from many areas, including dynamical systems, number theory, algebra, fluid mechanics, asymptotic analysis, knot theory, and probability. Enrollment limited.
Fall:D. A. Vogan
Spring:R. Bezrukavnikov
No required or recommended textbooks

Topology and Geometry

18.901 Introduction to Topology
______

Undergrad (Fall, Spring)
(Subject meets with18.9011)
Prereq: 18.100A, 18.100B, 18.100P, 18.100Q, or permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.901/
Lecture: TR9.30-11 (4-261)
______
Introduces topology, covering topics fundamental to modern analysis and geometry. Topological spaces and continuous functions, connectedness, compactness, separation axioms, and selected further topics such as function spaces, embedding theorems, dimension theory, or covering spaces and the fundamental group.
Fall:M. Hoyois
Spring:T. Walpuski
Textbooks (Fall 2016)

18.9011 Introduction to Topology
______

Graduate (Fall, Spring)
(Subject meets with18.901)
Prereq: 18.100A, 18.100B, 18.100P, 18.100Q, or permission of instructor
Units: 3-0-9
Lecture: TR9.30-11 (4-261)
______
Introduces topology, covering topics fundamental to modern analysis and geometry. Topological spaces and continuous functions, connectedness, compactness, separation axioms, and selected further topics such as function spaces, embedding theorems, dimension theory, or covering spaces and the fundamental group. Students in Course 18 must register for the undergraduate version, 18.901.
Fall:M. Hoyois
Spring:T. Walpuski
Textbooks (Fall 2016)

18.904 Seminar in Topology
______

Undergrad (Spring)
Prereq: 18.901
Units: 3-0-9
URL: http://math.mit.edu/classes/18.904/
______
Topics vary from year to year and include the fundamental group and covering spaces. Time permitting, also covers the relationship between these objects and the theory of knots. Students present and discuss the subject matter. Instruction and practice in written and oral communication provided. Enrollment limited.
G. Tabuada

18.905 Algebraic Topology I
______

Graduate (Fall)
Prereq: 18.701 or 18.703; 18.901
Units: 3-0-9
URL: http://math.mit.edu/classes/18.905/
Lecture: MWF11 (2-147) +final
______
Singular homology, CW complexes, universal coefficient and Künneth theorems, cohomology, cup products, Poincaré duality.
H. R. Miller
No required or recommended textbooks

18.906 Algebraic Topology II
______

Graduate (Spring)
Prereq: 18.905
Units: 3-0-9
URL: http://math.mit.edu/classes/18.906/
______
Continues the introduction to Algebraic Topology from 18.905. Topics include basic homotopy theory, spectral sequences, characteristic classes, and cohomology operations.
H. R. Miller

18.917 Topics in Algebraic Topology
______

Graduate (Spring) Can be repeated for credit
Prereq: 18.906
Units: 3-0-9
URL: http://math.mit.edu/classes/18.917/
______
Content varies from year to year. Introduces new and significant developments in algebraic topology with the focus on homotopy theory and related areas.
C. Barwick

18.919 Graduate Topology Seminar
______

Graduate (Fall)
Prereq: 18.906
Units: 3-0-9
Lecture: MW9.30-11 (2-151)
______
Study and discussion of important original papers in the various parts of algebraic topology. Open to all students who have taken 18.906 or the equivalent, not only prospective topologists.
G. Tabuada
No required or recommended textbooks

18.937 Topics in Geometric Topology
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.937
______
Content varies from year to year. Introduces new and significant developments in geometric topology.
E. Murphy

18.950 Differential Geometry
______

Undergrad (Fall)
(Subject meets with18.9501)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.950/2016fa/index.html
Lecture: MWF1 (2-131) +final
______
Introduction to differential geometry, centered on notions of curvature. Starts with curves in the plane, and proceeds to higher dimensional submanifolds. Computations in coordinate charts: first and second fundamental form, Christoffel symbols. Discusses the distinction between extrinsic and intrinsic aspects, in particular Gauss' theorema egregium. The Gauss-Bonnet theorem. Geodesics. Examples such as hyperbolic space.
H. Macbeth
No required or recommended textbooks

18.9501 Differential Geometry
______

Graduate (Fall)
(Subject meets with18.950)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
Lecture: MWF1 (2-131) +final
______
Introduction to differential geometry, centered on notions of curvature. Starts with curves in the plane, and proceeds to higher dimensional submanifolds. Computations in coordinate charts: first and second fundamental form, Christoffel symbols. Discusses the distinction between extrinsic and intrinsic aspects, in particular Gauss' theorema egregium. The Gauss-Bonnet theorem. Geodesics. Examples such as hyperbolic space. Students in Course 18 must register for the undergraduate version, 18.950.
H. Macbeth
No textbook information available

18.952 Theory of Differential Forms
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 18.101; 18.700 or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.952/
______
Multilinear algebra: tensors and exterior forms. Differential forms on Rn: exterior differentiation, the pull-back operation and the Poincaré lemma. Applications to physics: Maxwell's equations from the differential form perspective. Integration of forms on open sets of Rn. The change of variables formula revisited. The degree of a differentiable mapping. Differential forms on manifolds and De Rham theory. Integration of forms on manifolds and Stokes' theorem. The push-forward operation for forms. Thom forms and intersection theory. Applications to differential topology.
V. W. Guillemin

18.965 Geometry of Manifolds I
______

Graduate (Fall)
Prereq: 18.101, 18.950 or 18.952
Units: 3-0-9
URL: http://math.mit.edu/classes/18.965
Lecture: TR9.30-11 (2-135)
______
No required or recommended textbooks

18.966 Geometry of Manifolds II
______

Graduate (Spring)
Prereq: 18.965
Units: 3-0-9
URL: http://math.mit.edu/classes/18.966
______
Differential forms, introduction to Lie groups, the DeRham theorem, Riemannian manifolds, curvature, the Hodge theory. 18.966 is a continuation of 18.965 and focuses more deeply on various aspects of the geometry of manifolds. Contents vary from year to year, and can range from Riemannian geometry (curvature, holonomy) to symplectic geometry, complex geometry and Hodge-Kahler theory, or smooth manifold topology. Prior exposure to calculus on manifolds, as in 18.952, is recommended.
Fall:T. Walpuski
Spring:W. Minicozzi

18.968 Topics in Geometry
______

Not offered academic year 2017-2018Graduate (Fall) Can be repeated for credit
Prereq: 18.965
Units: 3-0-9
Lecture: TR9.30-11 (2-151)
______
Content varies from year to year.
T. Colding
No textbook information available

18.979 Graduate Geometry Seminar
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.979
______
Content varies from year to year. Study of classical papers in geometry and in applications of analysis to geometry and topology.
T. Mrowka

18.994 Seminar in Geometry
______

Undergrad (Fall)
Prereq: 18.101, 18.102, 18.103, or 18.112
Units: 3-0-9
Lecture: TR1-2.30 (2-151)
______
Students present and discuss subject matter taken from current journals or books. Topics vary from year to year. Instruction and practice in written and oral communication provided. Enrollment limited.
R. Hynd
Textbooks (Fall 2016)

18.999 Research in Mathematics
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Opportunity for study of graduate-level topics in mathematics under the supervision of a member of the department. For graduate students desiring advanced work not provided in regular subjects.
Information: W. Minicozzi
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

18.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Undergraduate research opportunities in mathematics. Permission required in advance to register for this subject. For further information, consult the departmental coordinator.
Information: J. W. Bush
Textbooks arranged individually

18.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of a Ph.D. thesis; to be arranged by the student and an appropriate MIT faculty member.
Information: W. Minicozzi
Textbooks arranged individually

18.S096 Special Subject in Mathematics
______

Undergrad (IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
______

18.S097 Special Subject in Mathematics
______

Undergrad (IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Opportunity for group study of subjects in mathematics not otherwise included in the curriculum. Offerings are initiated by members of the Mathematics faculty on an ad hoc basis, subject to departmental approval. 18.S097 is graded P/D/F.
Information: J. W. Bush

18.S995-18.S998 Special Subject in Mathematics
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
18.S996: URL: http://math.mit.edu/classes/18.S996/
18.S995: Lecture: TR2.30-4 (2-136)
Subject Cancelled 18.S998 Cancelled
______
Opportunity for group study of advanced subjects in mathematics not otherwise included in the curriculum. Offerings are initiated by members of the Mathematics faculty on an ad hoc basis, subject to departmental approval.
Information: J. W. Bush
18.S995: No required or recommended textbooks


left arrow|18.01-18.499|18.50-18.THG|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 20: Biological Engineering
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Course 20: Biological Engineering
Fall 2016


20.002 Metakaryotic Biology and Epidemiology
______

Undergrad (Fall)
(Subject meets with20.A02)
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: F3-5 (56-711)
______
Introduces non-eukaryotic metakaryotic cells that serve as the stem cells of human fetal/juvenile growth and development. Considers their peculiar modes of genome organization in chromosomal rings, replication via dsRNA/DNA intermediates and amitotic segregation. Explores the hypothesis that high mutation rates in these cells lead to cancers and atherosclerotic plaques and account for the increasing death rates observed with human age.
W. Thilly
No textbook information available

20.020 Introduction to Biological Engineering Design Using Synthetic Biology
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with20.385)
Prereq: None
Units: 3-3-3
______
Project-based introduction to the engineering of synthetic biological systems. Throughout the term, students develop projects that are responsive to real-world problems of their choosing, and whose solutions depend on biological technologies. Lectures, discussions, and studio exercises will introduce components and control of prokaryotic and eukaryotic behavior; DNA synthesis, standards, and abstraction in biological engineering; and issues of human practice, including biological safety, security, ethics, and ownership, sharing, and innovation. Preference to freshmen.
N. Kuldell

20.102 Stem Cells in Organogenesis, Carcinogenesis, and Atherogenesis
______

Undergrad (Fall)
(Subject meets with20.215)
Prereq: Calculus II (GIR), Biology (GIR), Chemistry (GIR)
Units: 3-0-9
Lecture: TR1-2.30 (16-220)
______
Study of the amitotic metakaryotic stem cells in fetal/juvenile organogenesis and wound healing. Explores their roles as stem cells in clonal diseases such as cancers and atherosclerosis. Application of a hypermutable/mutator stem cell model to the analysis of age-specific mortality from clonal diseases. Students taking 20.215 do additional research and computer modeling.
E. V. Gostjeva, W. G. Thilly
No textbook information available

20.104[J] Environmental Cancer Risks, Prevention, and Therapy
______

Undergrad (Spring)
(Same subject as1.081[J])
Prereq: Calculus II (GIR), Biology (GIR), Chemistry (GIR)
Units: 3-0-9
______
Analysis of the history of cancer and vascular disease mortality rates in predominantly European- and African-American US cohorts, 1895-2010, to discover specific historical shifts. Shifts identified are explored in terms of contemporaneously changing environmental risk factors: air-, food- and water-borne chemicals; subclinical infections; diet and lifestyles. Role of occupational data identifying general risk factors. Considers the hypotheses that environmental factors affect metakaryotic stem cell mutation rates in fetuses and juveniles and/or the growth rates of preneoplastic stem cells in adults. Interaction of environmental and inherited risks. Introduces the use of metakaryocidal drugs to treat cancer in clinical trials.
W. Thilly, R. McCunney

20.106[J] Systems Microbiology
______

Undergrad (Fall)
(Same subject as1.084[J])
Prereq: Chemistry (GIR), Biology (GIR)
Units: 3-0-9
Lecture: TR2.30-4 (56-614)
______
Introductory microbiology from a systems perspective - considers microbial diversity and the integration of data from a molecular, cellular, organismal, and ecological context to understand the interaction of microbial organisms with their environment. Special emphasis on specific viral, bacterial, and eukaryotic microorganisms and their interaction with animal hosts with focus on contemporary problems in areas such as vaccination, emerging disease, antimicrobial drug resistance, and toxicology.
E. Alm, J. Niles
No textbook information available

20.109 Laboratory Fundamentals in Biological Engineering
______

Undergrad (Fall, Spring) Institute Lab
Prereq: Biology (GIR), Chemistry (GIR), 6.0002, 18.03, 20.110
Units: 2-8-5
Lecture: TR11 (16-220) Lab: TR1-5 (56-322) or WF1-5 (56-322)
______
Introduces experimental biochemical and molecular techniques from a quantitative engineering perspective. Experimental design, data analysis, and scientific communication form the underpinnings of this subject. Examples of discovery-based experimental modules include DNA engineering in which students design, construct, and use genetic material; parts engineering, which emphasizes protein design and quantitative assessment of protein performance; systems engineering, in which students consider genome-wide consequences of genetic perturbations; and biomaterials engineering, in which students use biologically-encoded devices to design and build materials. Students complete some laboratory time online in advance of each class. Enrollment limited; priority to Course 20 majors.
Fall:A. Belcher, B. Engelward, M. Jonas, N. Lyell, L. McClain
Spring:A. Belcher, L. Samson, M. Jonas, N. Lyell, L. McClain
No textbook information available

20.110[J] Thermodynamics of Biomolecular Systems
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
(Same subject as2.772[J])
Prereq: Calculus II (GIR), Chemistry (GIR), Physics I (GIR)
Units: 5-0-7
Lecture: MWF10 (4-270) Recitation: TR10 (26-168) or TR1 (66-154) or TR4 (56-169) +final
______
Equilibrium properties of macroscopic and microscopic systems. Basic thermodynamics: state of a system, state variables. Work, heat, first law of thermodynamics, thermochemistry. Second and third law of thermodynamics: entropy and its statistical basis, Gibbs function. Chemical equilibrium of reactions in gas and solution phase. Macromolecular structure and interactions in solution. Driving forces for molecular self-assembly. Binding cooperativity, solvation, titration of macromolecules.
Fall:M. Birnbaum C. Voigt
Spring:E. Alm, C. Voigt
No textbook information available

20.129[J] Biological Circuit Engineering Laboratory
______

Undergrad (Spring) Institute Lab
(Same subject as6.129[J])
Prereq: Biology (GIR), Calculus II (GIR)
Units: 2-8-2
______
Students assemble individual genes and regulatory elements into larger-scale circuits; they experimentally characterize these circuits in yeast cells using quantitative techniques, including flow cytometry, and model their results computationally. Emphasizes concepts and techniques to perform independent experimental and computational synthetic biology research. Discusses current literature and ongoing research in the field of synthetic biology. Instruction and practice in oral and written communication provided. Enrollment limited.
T. Lu, R. Weiss

20.200 Biological Engineering Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 1-0-2 [P/D/F]
Lecture: F12 (32-155)
______
Weekly one-hour seminars covering graduate student research and presentations by invited speakers. Limited to BE graduate students.
B. Engelward
No textbook information available

20.201 Fundamentals of Drug Development
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 4-0-8
Lecture: MW1.30-3 (56-614) Recitation: F1.30 (56-614)
______
Addresses the scientific basis for the development of new drugs. First half of term begins with an overview of the drug discovery process, followed by fundamental principles of pharmacokinetics, pharmacodynamics, metabolism, and the mechanisms by which drugs cause therapeutic and toxic responses. Second half applies principles to case studies and literature discussions of current problems with specific drugs, drug classes, and therapeutic targets.
P. C. Dedon, M. A. Murcko, R. Sasisekharan
No textbook information available

20.202 In vivo Models: Principles and Practices
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 1-1-4
______
Selected aspects of anatomy, histology, immuno-cytochemistry, in situ hybridization, physiology, and cell biology of mammalian organisms and their pathogens. Subject material integrated with principles of toxicology, in vivo genetic engineering, and molecular biology. A lab/demonstration period each week involves experiments in anatomy (in vivo), physiology, and microscopy to augment the lectures. Offered first half of spring term.
J. G. Fox, B. Marini, M. Whary

20.203[J] Neurotechnology in Action
______

Graduate (Fall)
(Same subject as9.123[J])
Prereq: Permission of instructor
Units: 3-6-3
Lecture: TR2.30-4 (46-4062)
______
Offers a fast-paced introduction to numerous laboratory methods at the forefront of modern neurobiology. Comprises a sequence of modules focusing on neurotechnologies that are developed and used by MIT research groups. Each module consists of a background lecture and 1-2 days of firsthand laboratory experience. Topics typically include optical imaging, optogenetics, high throughput neurobiology, MRI/fMRI, advanced electrophysiology, viral and genetic tools, and connectomics.
A. Jasanoff, E. Boyden, M. Jonas
No required or recommended textbooks

20.205[J] Principles and Applications of Genetic Engineering for Biotechnology and Neuroscience
______

Undergrad (Spring)
(Same subject as9.26[J])
Prereq: 7.28, 7.32, or 20.020; 9.01 or 9.09
Units: 3-0-9
______
Covers principles underlying current and future genetic engineering approaches, ranging from single cellular organisms to whole animals. Focuses on development and invention of technologies for engineering biological systems at the genomic level, and applications of engineered biological systems for medical and biotechnological needs, with particular emphasis on genetic manipulation of the nervous system. Design projects by students.
F. Zhang

20.207 Biotechnologies in Infectious Disease
______

Graduate (Spring)
Prereq: 7.06, permission of instructor
Units: 3-0-9
______
In-depth exploration of current and emerging technologies used in the surveillance, diagnosis, understanding, treatment and prevention of infectious diseases, drawing on basic science and engineering principles. Develops practical problem-solving skills relevant to infectious disease issues on a global scale. In partnership with students in Southeast Asia via edX, MIT students participate in global collaborations focusing on case studies of distinct pathogens. Together, both groups of students then apply these principles longitudinally in a team-based project on technology applications in infectious disease that culminates in a presentation at the end of the term.
P. C. Dedon, J.C. Niles, R. Sasisekharan

20.213 DNA Damage and Genomic Instability
______

Graduate (Spring)
Prereq: 5.07, 7.05, permission of instructor
Units: 4-0-8
______
Focuses on biochemistry and molecular mechanisms of DNA replication and DNA repair. Analyzes chemistry of DNA damaging events, and analyzes mutagenic and toxic consequences of modifications to DNA structure. Also presents the contrasting perspective that normal DNA processing leads to mutations. Moves from analysis and discussion of key DNA repair pathways to connections between DNA repair and human diseases. Discusses in-depth the chemistry and biochemistry of DNA metabolism. Includes current literature related to the molecular mechanisms of radiation and chemotherapy.
B. P. Engelward, L. Samson

20.215 Macroepidemiology, Population Genetics, and Stem Cell Biology of Human Clonal Diseases
______

Graduate (Fall)
(Subject meets with20.102)
Prereq: Calculus II (GIR), 1.00
Units: 3-0-15
Lecture: TR1-2.30 (16-220)
______
Studies the logic and technology needed to discover genetic and environmental risks for common human cancers and vascular diseases. Includes an introduction to metakaryotic stem cell biology. Analyzes large, organized historical public health databases using quantitative cascade computer models that include population stratification of stem cell mutation rates in fetal/juvenile tissues and growth rates in preneoplastic colonies and atherosclerotic plaques. Means to test hypotheses (CAST) that certain genes carry mutations conferring risk for common cancers via genetic analyses in large human cohorts.
W. G. Thilly
No textbook information available

20.219 Selected Topics in Biological Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Detailed discussion of selected topics of current interest. Classwork in various areas not covered by regular subjects.
Staff
No textbook information available

20.260 Analysis and Presentation of Complex Biological Data
______

Undergrad (IAP)
Prereq: Permission of instructor
Units: 2-0-2 [P/D/F]
______
Illustrates best practices in the statistical analysis of complex biological datasets and the graphical representation of such analyses. Covers fundamental concepts in probability and statistical theory as well as principles of information design. Provides mathematical concepts and tools that enable students to make sound judgments about the application of statistical methods and to present statistical results in clear and compelling visual formats. Assignments focus on key concepts and their application to practical examples. Assumes basic knowledge of calculus and programming in MATLAB or R.
P. Blainey

20.300 Advanced Workshop in Biological Engineering Communication: Professors Share Their Practices
______

Undergrad (IAP)
Prereq: Permission of instructor
Units: 3-0-0 [P/D/F]
______
Working scientists and engineers discuss best practices for written, visual, and oral communication in the classroom, the lab, and the workplace. In a series of lectures, successful academics and industry professionals share how they prepare papers, talks, and graphics. Recitations allow deeper exploration of the lecture topics. With faculty guidance, students develop their own projects during workshops. Emphasizes systematic approaches and transferable skills such as effective drafting and revision. Topics include creating compelling visuals to represent data and concepts; formal/informal writing, from research papers to cover letters; and developing memorable talks and presentations. Examples drawn from biological engineering research. Enrollment limited; preference to Course 20 majors.
E. Alm, J. Goldstein, A. Stachowiak

20.305[J] Principles of Synthetic Biology
______

Undergrad (Fall)
(Same subject as6.580[J])
(Subject meets with6.589[J],20.405[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (9-057) +final
______
Introduces the basics of synthetic biology, including quantitative cellular network characterization and modeling. Considers the discovery and genetic factoring of useful cellular activities into reusable functions for design. Emphasizes the principles of biomolecular system design and diagnosis of designed systems. Illustrates cutting-edge applications in synthetic biology and enhances skills in analysis and design of synthetic biological applications. Students taking graduate version complete additional assignments.
R. Weiss
No textbook information available

20.309[J] Instrumentation and Measurement for Biological Systems
______

Undergrad (Fall, Spring)
(Same subject as2.673[J])
(Subject meets with20.409)
Prereq: Biology (GIR), Physics II (GIR), 6.0002, 18.03; or permission of instructor
Units: 3-6-3
Lecture: TR12 (32-155) Recitation: F12 (56-114)
______
Sensing and measurement aimed at quantitative molecular/cell/tissue analysis in terms of genetic, biochemical, and biophysical properties. Methods include light and fluorescence microscopies, and electro-mechanical probes (atomic force microscopy, optical traps, MEMS devices). Application of statistics, probability, signal and noise analysis, and Fourier techniques to experimental data. Enrollment limited; preference to Course 20 undergraduates.
Fall:P. Blainey, S. Manalis, E. Frank, S. Wasserman, J. Bagnall
Spring:E. Boyden, P. So, S. Wasserman, J. Bagnall, E. Frank
No textbook information available

20.310[J] Molecular, Cellular, and Tissue Biomechanics
______

Undergrad (Spring)
(Same subject as2.797[J],3.053[J],6.024[J])
Prereq: 2.370 or 2.772J; 18.03 or 3.016; Biology (GIR)
Units: 4-0-8
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, A. J. Grodzinsky, K. Van Vliet

20.315 Physical Biology
(New)
______

Undergrad (Spring)
(Subject meets with20.415)
Prereq: 20.110, 5.60, or permission of instructor
Units: 3-0-9
______
Focuses on current major research topics in quantitative, physical biology. Covers synthetic structural biology, synthetic cell biology, microbial systems biology and evolution, cellular decision making, neuronal circuits, and development and morphogenesis. Emphasizes current motivation and historical background, state-of-the-art measurement methodologies and techniques, and quantitative physical modeling frameworks. Experimental techniques include structural biology, next-generation sequencing, fluorescence imaging and spectroscopy, and quantitative biochemistry. Modeling approaches include stochastic rate equations, statistical thermodynamics, and statistical inference. Students taking graduate version complete additional assignments.
M. Bathe, P. Blainey

20.320 Analysis of Biomolecular and Cellular Systems
______

Undergrad (Fall)
Prereq: 20.110, 18.03, 6.0002;Coreq: 5.07 or 7.05
Units: 4-0-8
Lecture: TR9.30-11 (32-141) Recitation: M3 (56-114) or F10 (4-153)
______
Analysis of molecular and cellular processes across a hierarchy of scales, including genetic, molecular, cellular, and cell population levels. Topics include gene sequence analysis, molecular modeling, metabolic and gene regulation networks, signal transduction pathways and cell populations in tissues. Emphasis on experimental methods, quantitative analysis, and computational modeling.
F. White, K. D. Wittrup
No textbook information available

20.330[J] Fields, Forces and Flows in Biological Systems
______

Undergrad (Spring)
(Same subject as2.793[J],6.023[J])
Prereq: Physics II (GIR); 2.005, 6.021, or permission of instructor,Coreq: 20.309
Units: 4-0-8
______
Introduction to electric fields, fluid flows, transport phenomena and their application to biological systems. Flux and continuity laws, Maxwell's equations, electro-quasistatics, electro-chemical-mechanical driving forces, conservation of mass and momentum, Navier-Stokes flows, and electrokinetics. Applications include biomolecular transport in tissues, electrophoresis, and microfluidics.
J. Han, S. Manalis

20.345[J] Bioinstrumentation Project Lab
______

Undergrad (Spring)
(Same subject as6.123[J])
Prereq: Biology (GIR), and 2.004 or 6.003; or 20.309; or permission of instructor
Units: 2-7-3
______
In-depth examination of instrumentation design, principles and techniques for studying biological systems, from single molecules to entire organisms. Lectures cover optics, advanced microscopy techniques, electronics for biological measurement, magnetic resonance imaging, computed tomography, MEMs, microfluidic devices, and limits of detection. Students select two lab exercises during the first half of the semester and complete a final design project in the second half. Lab emphasizes design process and skillful realization of a robust system. Enrollment limited; preference to Course 20 majors and minors.
E. Boyden, M. Jonas, S. F. Nagle, P. So, S. Wasserman, M. F. Yanik

20.352 Principles of Neuroengineering
(New)
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with9.422[J],20.452[J],MAS.881[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Covers how to innovate technologies for brain analysis and engineering, for accelerating the basic understanding of the brain, and leading to new therapeutic insight and inventions. Focuses on using physical, chemical and biological principles to understand technology design criteria governing ability to observe and alter brain structure and function. Topics include optogenetics, noninvasive brain imaging and stimulation, nanotechnologies, stem cells and tissue engineering, and advanced molecular and structural imaging technologies. Includes design projects. Students taking graduate version complete additional assignments. Designed for students with engineering maturity who are ready for design.
E. S. Boyden, III

20.361[J] Molecular and Engineering Aspects of Biotechnology
______

Undergrad (Spring)
(Same subject as7.37[J],10.441[J])
Prereq: 2.005, 3.012, 5.60, or 20.110; 7.06; or permission of instructor
Units: 4-0-8
Credit cannot also be received for7.371
______
Covers biological and bioengineering principles underlying the development and therapeutic use of recombinant proteins and stem cells; glycoengineering of recombinant proteins; normal and pathological signaling by growth factors and their receptors; receptor trafficking; monoclonal antibodies as therapeutics; protein pharmacology and delivery; stem cell-derived tissues as therapeutics; RNA therapeutics; combinatorial protein engineering; and new antitumor drugs.
H. Lodish, L. Griffith

20.363[J] Biomaterials Science and Engineering
______

Undergrad (Fall)
(Same subject as3.055[J])
(Subject meets with3.963[J],20.463[J])
Prereq: 3.034, 20.110, or permission of instructor
Units: 3-0-9
Lecture: MW11-12.30 (56-614)
______
Covers, at a molecular scale, the analysis and design of materials used in contact with biological systems, and biomimetic strategies aimed at creating new materials based on principles found in biology. Topics include molecular interaction between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of materials science to problems in tissue engineering, drug delivery, vaccines, and cell-guiding surfaces. Students taking graduate version complete additional assignments.
D. Irvine, K. Ribbeck
No textbook information available

20.365 Engineering the Immune System in Cancer and Beyond
(New)
______

Undergrad (Spring)
(Subject meets with20.465)
Prereq: 20.110, 5.60, or 7.10; permission of instructor
Units: 3-0-9
______
Examines strategies in clinical and preclinical development for manipulating the immune system to treat and protect against disease. Begins with brief review of immune system. Discusses interaction of tumors with the immune system, followed by approaches by which the immune system can be modulated to attack cancer. Also covers strategies based in biotechnology, chemistry, materials science, and molecular biology to induce immune responses to treat infection, transplantation, and autoimmunity. Students taking graduate version complete additional assignments.
D. Irvine, M. Birnbaum

20.370[J] Cellular Neurophysiology
______

Undergrad (Fall)
(Same subject as2.791[J],6.021[J])
(Subject meets with2.794[J],6.521[J],20.470[J],HST.541[J])
Prereq: Physics II (GIR); 18.03; 2.005, 6.002, 6.003, 6.071, 10.301, 20.110, or permission of instructor
Units: 5-2-5
Lecture: MWF10 (32-144) Lab: TBA Recitation: T12 (34-303) or T4 (34-302) +final
______
Integrated overview of the biophysics of cells from prokaryotes to neurons, with a focus on mass transport and electrical signal generation across cell membrane. First half of course focuses on mass transport through membranes: diffusion, osmosis, chemically mediated, and active transport. Second half focuses on electrical properties of cells: ion transport to action potentials in electrically excitable cells. Synaptic transmission. Electrical properties interpreted via kinetic and molecular properties of single voltage-gated ion channels. Laboratory and computer exercises illustrate the concepts. Students taking graduate version complete different assignments. Preference to juniors and seniors.
J. Han, T. Heldt, J. Voldman
Textbooks (Fall 2016)

20.380 Biological Engineering Design
______

Undergrad (Fall, Spring)
Prereq: 7.06, 20.320, 20.330;Coreq: 20.309
Units: 5-0-7
Lecture: TR10-12 (56-614) Recitation: TR9 (56-614)
______
Illustrates how knowledge and principles of biology, biochemistry, and engineering are integrated to create new products for societal benefit. Uses case study format to examine recently developed products of pharmaceutical and biotechnology industries: how a product evolves from initial idea, through patents, testing, evaluation, production, and marketing. Emphasizes scientific and engineering principles, as well as the responsibility scientists, engineers, and business executives have for the consequences of their technology. Instruction and practice in written and oral communication provided. Enrollment limited; preference to Course 20 undergraduates.
Fall:J. Collins, A. Koehler
Spring:J. Essigmann, K. Ribbeck
No textbook information available

20.385 Understanding Current Research in Synthetic Biology
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with20.020)
Prereq: 20.109, 20.320; or permission of instructor
Units: 3-3-3
______
Provides an in-depth understanding of the state of research in synthetic biology. Critical evaluation of primary research literature covering a range of approaches to the design, modeling and programming of cellular behaviors. Focuses on developing the skills needed to read, present and discuss primary research literature, and to manage and lead small teams. Students mentor a small undergraduate team of 20.020 students. Open to advanced students with appropriate background in biology.
N. Kuldell

20.390[J] Foundations of Computational and Systems Biology
______

Undergrad (Spring)
(Same subject as6.802[J])
(Subject meets with6.874[J],20.490,HST.506[J])
Prereq: Biology (GIR), 6.0002 or 6.01; 7.05; or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/7.91/
______
Provides an introduction to computational and systems biology. Includes units on the analysis of protein and nucleic acid sequences, protein structures, and biological networks. Presents principles and methods used for sequence alignment, motif finding, expression array analysis, structural modeling, structure design and prediction, and network analysis and modeling. Techniques include dynamic programming, Markov and hidden Markov models, Bayesian networks, clustering methods, and energy minimization approaches. Exposes students to emerging research areas. Designed for students with strong backgrounds in either molecular biology or computer science. Some foundational material covering basic programming skills, probability and statistics is provided for students with less quantitative backgrounds. Students taking graduate version complete additional assignments.
D. K. Gifford, T. S. Jaakkola

20.405[J] Principles of Synthetic Biology
______

Graduate (Fall)
(Same subject as6.589[J])
(Subject meets with6.580[J],20.305[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (9-057) +final
______
Introduces the basics of synthetic biology, including quantitative cellular network characterization and modeling. Considers the discovery and genetic factoring of useful cellular activities into reusable functions for design. Emphasizes the principles of biomolecular system design and diagnosis of designed systems. Illustrates cutting-edge applications in synthetic biology and enhances skills in analysis and design of synthetic biological applications. Students taking graduate version complete additional assignments.
R. Weiss
No textbook information available

20.409 Biological Engineering II: Instrumentation and Measurement
______

Graduate (Fall, Spring)
(Subject meets with2.673[J],20.309[J])
Prereq: Permission of instructor
Units: 2-7-3
Lecture: TR12 (32-155) Recitation: F12 (56-114)
______
Sensing and measurement aimed at quantitative molecular/cell/tissue analysis in terms of genetic, biochemical, and biophysical properties. Methods include light and fluorescence microscopies, electronic circuits, and electro-mechanical probes (atomic force microscopy, optical traps, MEMS devices). Application of statistics, probability, signal and noise analysis, and Fourier techniques to experimental data. Limited to 5 graduate students.
Fall:P. Blainey, S. Manalis, S. Wasserman, J. Bagnall, E. Frank
Spring:E. Boyden, P. So, S. Wasserman, J. Bagnall, E. Frank
No textbook information available

20.410[J] Molecular, Cellular, and Tissue Biomechanics
______

Graduate (Fall)
(Same subject as2.798[J],3.971[J],6.524[J],10.537[J])
Prereq: Biology (GIR); 2.002, 2.006, 6.013, 10.301, or 10.302
Units: 3-0-9
Lecture: TR10.30-12 (2-143)
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, K. J. Van Vliet
No textbook information available

20.415 Physical Biology
______

Graduate (Spring)
(Subject meets with20.315)
Prereq: Permission of instructor
Units: 3-0-9
______
Focuses on current major research topics in quantitative, physical biology. Topics include synthetic structural biology, synthetic cell biology, microbial systems biology and evolution, cellular decision making, neuronal circuits, and development and morphogenesis. Emphasizes current motivation and historical background, state-of-the-art measurement methodologies and techniques, and quantitative physical modeling frameworks. Experimental techniques include structural biology, next-generation sequencing, fluorescence imaging and spectroscopy, and quantitative biochemistry. Modeling approaches include stochastic rate equations, statistical thermodynamics, and statistical inference. Students taking graduate version complete additional assignments.
M. Bathe, P. Blainey

20.416[J] Topics in Biophysics and Physical Biology
______

Graduate (Fall)
(Same subject as7.74[J],8.590[J])
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: F1-2.30 (56-167)
______
Provides broad exposure to research in biophysics and physical biology, with emphasis on the critical evaluation of scientific literature. Weekly meetings include in-depth discussion of scientific literature led by distinct faculty on active research topics. Each session also includes brief discussion of non-research topics including effective presentation skills, writing papers and fellowship proposals, choosing scientific and technical research topics, time management, and scientific ethics.
I. Cisse, N. Fakhri, M. Guo
No required or recommended textbooks

20.420[J] Biomolecular Kinetics and Cellular Dynamics
______

Graduate (Fall)
(Same subject as10.538[J])
Prereq: 7.06, 18.03
Units: 3-0-9
Lecture: TR9.30-11 +final
______
Fundamental analysis of biological rate processes using approaches from biomolecular reaction kinetics and dynamical systems engineering. Topics include binding and hybridization interactions, enzyme reactions, metabolic cycles, gene regulation, receptor/ligand trafficking systems, intra- and intercellular signaling, and cell population dynamics.
A. Jasanoff, E. Fraenkel
No textbook information available

20.430[J] Fields, Forces, and Flows in Biological Systems
______

Graduate (Fall)
(Same subject as2.795[J],6.561[J],10.539[J])
Prereq: 6.013, 2.005, 10.302, or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/beh.430/www/
Lecture: MW1-2.30 (32-124)
______
Molecular diffusion, diffusion-reaction, conduction, convection in biological systems; fields in heterogeneous media; electrical double layers; Maxwell stress tensor, electrical forces in physiological systems. Fluid and solid continua: equations of motion useful for porous, hydrated biological tissues. Case studies of membrane transport, electrode interfaces, electrical, mechanical, and chemical transduction in tissues, convective-diffusion/reaction, electrophoretic, electroosmotic flows in tissues/MEMs, and ECG. Electromechanical and physicochemical interactions in cells and biomaterials; musculoskeletal, cardiovascular, and other biological and clinical examples.
M. Bathe, A. J. Grodzinsky
Textbooks (Fall 2016)

20.440 Analysis of Biological Networks
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 4-0-8
______
Conceptual and experimental approaches to analyzing complex biological networks and systems, from molecules to human populations, focusing on human pathophysiology and disease. Moving from single component analysis to pathways and networks, combines didactic lectures with in-depth analysis of current literature. Emphasizes the chemistry and biochemistry of underlying biological processes. Topics include linking genes/SNPs to disease, defining pathways, analysis of pathways in vivo, systems-level analysis, and applications of network biology. First half of term focuses on fundamental biological processes and tools/analyses needed by biological engineers, and the second half elaborates on these fundamentals by covering complex biological processes. Students acquire skills in the fundamentals of grant preparation using an NIH format and make an oral presentation.
P. Blainey, E. Fraenkel, M. Yaffe

20.445[J] Methods and Problems in Microbiology
______

Graduate (Fall)
(Same subject as1.86[J],7.492[J])
Prereq: None
Units: 3-0-9
Lecture: W EVE (3-6 PM) (4-146)
______
Students will read and discuss primary literature covering key areas of microbial research with emphasis on methods and approaches used to understand and manipulate microbes. Preference to first-year Microbiology and Biology students.
M. Laub
No required or recommended textbooks

20.446[J] Microbial Genetics and Evolution
______

Graduate (Fall)
(Same subject as1.87[J],7.493[J],12.493[J])
Prereq: 7.03, 7.05, or permission of instructor
Units: 4-0-8
Lecture: TR12.30-2.30 (66-160)
______
Covers aspects of microbial genetic and genomic analyses, central dogma, horizontal gene transfer, and evolution.
A. D. Grossman, G. Fournier
Textbooks (Fall 2016)

20.450 Molecular and Cellular Pathophysiology
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 20.420, 20.440; or permission of instructor
Units: 4-0-8
Subject Cancelled Subject Cancelled
______
Compares the complex molecular and cellular interactions in health and disease between commensal microbial communities, pathogens and the human or animal host. Special focus is given to current research on microbe/host interactions, infection of significant importance to public health, and chronic infectious disease. Classwork will include lecture, but emphasize critical evaluation and class discussion of recent scientific papers, and the development of new research agendas in the fields presented.
J. C. Niles, J. Runstadler

20.451[J] Design of Medical Devices and Implants
______

Graduate (Spring)
(Same subject as2.782[J],3.961[J],HST.524[J])
Prereq: Chemistry (GIR), Biology (GIR), Physics I (GIR); or permission of instructor
Units: 3-0-9
______
Solution of clinical problems by use of implants and other medical devices. Systematic use of cell-matrix control volumes. The role of stress analysis in the design process. Anatomic fit: shape and size of implants. Selection of biomaterials. Instrumentation for surgical implantation procedures. Preclinical testing for safety and efficacy: risk/benefit ratio assessment. Evaluation of clinical performance: design of clinical trials. Project materials drawn from orthopedic devices, soft tissue implants, artificial organs, and dental implants.
I. V. Yannas, M. Spector

20.452[J] Principles of Neuroengineering
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as9.422[J],MAS.881[J])
(Subject meets with20.352)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://neuro.media.mit.edu/classes/prinneuro/
______
Covers how to innovate technologies for brain analysis and engineering, for accelerating the basic understanding of the brain, and leading to new therapeutic insight and inventions. Focuses on using physical, chemical and biological principles to understand technology design criteria governing ability to observe and alter brain structure and function. Topics include optogenetics, noninvasive brain imaging and stimulation, nanotechnologies, stem cells and tissue engineering, and advanced molecular and structural imaging technologies. Includes design projects. Designed for students with engineering maturity who are ready for design. Students taking graduate version complete additional assignments.
E. S. Boyden, III

20.454[J] Revolutionary Ventures: How to Invent and Deploy Transformative Technologies
______

Graduate (Fall)
(Same subject as9.455[J],15.128[J],MAS.883[J])
Prereq: Permission of instructor
Units: 2-0-7
URL: http://neuro.media.mit.edu/classes/neuroven/
Lecture: R2-4 (E15-341)
______
Seminar on envisioning and building ideas and organizations to accelerate engineering revolutions. Focuses on emerging technology domains, such as neurotechnology, imaging, cryotechnology, gerontechnology, and bio-and-nano fabrication. Draws on historical examples as well as live case studies of existing or emerging organizations, including labs, institutes, startups, and companies. Goals range from accelerating basic science to developing transformative products or therapeutics. Each class is devoted to a specific area, often with invited speakers, exploring issues from the deeply technical through the strategic. Individually or in small groups, students prototype new ventures aimed at inventing and deploying revolutionary technologies.
J. Bonsen, J. Jacobson
No textbook information available

20.463[J] Biomaterials Science and Engineering
______

Graduate (Fall)
(Same subject as3.963[J])
(Subject meets with3.055[J],20.363[J])
Prereq: 3.034, 20.110, or permission of instructor
Units: 3-0-9
Lecture: MW11-12.30 (56-614)
______
Covers, at a molecular scale, the analysis and design of materials used in contact with biological systems, and biomimetic strategies aimed at creating new materials based on principles found in biology. Topics include molecular interaction between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of materials science to problems in tissue engineering, drug delivery, vaccines, and cell-guiding surfaces. Students taking graduate version complete additional assignments.
D. Irvine, K. Ribbeck
No textbook information available

20.465 Engineering the Immune System in Cancer and Beyond
(New)
______

Graduate (Spring)
(Subject meets with20.365)
Prereq: Permission of instructor
Units: 3-0-9
______
Examines strategies in clinical and preclinical development for manipulating the immune system to treat and protect against disease. Begins with brief review of immune system. Discusses interaction of tumors with the immune system, followed by approaches by which the immune system can be modulated to attack cancer. Also covers strategies based in biotechnology, chemistry, materials science, and molecular biology to induce immune responses to treat infection, transplantation, and autoimmunity. Students taking graduate version complete additional assignments.
D. Irvine, M. Birnbaum

20.470[J] Cellular Neurophysiology
______

Graduate (Fall)
(Same subject as2.794[J],6.521[J],HST.541[J])
(Subject meets with2.791[J],6.021[J],20.370[J])
Prereq: Physics II (GIR); 18.03; 2.005, 6.002, 6.003, 6.071, 10.301, 20.110, or permission of instructor
Units: 5-2-5
Lecture: MWF10 (32-144) Lab: TBA Recitation: T12 (34-303) or T4 (34-302) +final
______
Meets with undergraduate subject 6.021J. Requires the completion of more advanced home problems and/or an additional project.
J. Han, T. Heldt
Textbooks (Fall 2016)

20.482[J] Foundations of Algorithms and Computational Techniques in Systems Biology
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as6.581[J])
(Subject meets with6.503)
Prereq: 6.021, 6.034, 6.046, 6.336, 18.417, or permission of instructor
Units: 3-0-9
______
Illustrates computational approaches to solving problems in systems biology. Uses a series of case studies to demonstrate how an effective match between the statement of a biological problem and the selection of an appropriate algorithm or computational technique can lead to fundamental advances. Covers several discrete and numerical algorithms used in simulation, feature extraction, and optimization for molecular, network, and systems models in biology. Students taking graduate version complete additional assignments.
B. Tidor, J. K. White

20.483[J] Noninvasive Imaging in Biology and Medicine
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as9.173[J],22.56[J],HST.561[J])
Prereq: 18.03, 8.03, or permission of instructor
Units: 3-0-9
______
Background in the theory and application of noninvasive imaging methods in biology and medicine, with emphasis on neuroimaging. Focuses on the modalities most frequently used in scientific research (x-ray CT, PET/SPECT, MRI, and optical imaging), and includes discussion of molecular imaging approaches used in conjunction with these scanning methods. Lectures are supplemented by in-class discussions of problems in research and demonstrations of imaging systems.
A. Jasanoff

20.486[J] Case Studies and Strategies in Drug Discovery and Development
______

Graduate (Spring)
(Same subject as7.549[J],15.137[J],HST.916[J])
Prereq: None
Units: 2-0-4
______
Aims to develop appreciation for the stages of drug discovery and development, from target identification, to the submission of preclinical and clinical data to regulatory authorities for marketing approval. Following introductory lectures on the process of drug development, students working in small teams analyze how one of four new drugs or drug candidates traversed the discovery/development landscape. For each case, an outside expert from the sponsoring drug company or pivotal clinical trial principal investigator provides guidance and critiques the teams' presentations to the class.
S. R. Tannenbaum, A. J. Sinskey, A. W. Wood

20.487[J] Optical Microscopy and Spectroscopy for Biology and Medicine
______

Graduate (Spring)
Not offered regularly; consult department
(Same subject as2.715[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces the theory and the design of optical microscopy and its applications in biology and medicine. The course starts from an overview of basic optical principles allowing an understanding of microscopic image formation and common contrast modalities such as dark field, phase, and DIC. Advanced microscopy imaging techniques such as total internal reflection, confocal, and multiphoton will also be discussed. Quantitative analysis of biochemical microenvironment using spectroscopic techniques based on fluorescence, second harmonic, Raman signals will be covered. We will also provide an overview of key image processing techniques for microscopic data.
P. T. So, C. Sheppard

20.490 Foundations of Computational and Systems Biology
______

Graduate (Spring)
(Subject meets with6.802[J],6.874[J],20.390[J],HST.506[J])
Prereq: Biology (GIR), 6.0002 or 6.01; or 7.05; or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/7.91/
______
Provides an introduction to computational and systems biology. Includes units on the analysis of protein and nucleic acid sequences, protein structures, and biological networks. Presents principles and methods used for sequence alignment, motif finding, expression array analysis, structural modeling, structure design and prediction, and network analysis and modeling. Techniques include dynamic programming, Markov and hidden Markov models, Bayesian networks, clustering methods, and energy minimization approaches. Exposes students to emerging research areas. Designed for students with strong backgrounds in either molecular biology or computer science. Some foundational material covering basic programming skills, probability and statistics is provided for students with less quantitative backgrounds. Students taking graduate version complete additional assignments.
D. K. Gifford, T. S. Jaakkola

20.507[J] Biological Chemistry I
______

Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject as5.07[J])
Prereq: 5.12
Units: 5-0-7
Credit cannot also be received for7.05
Lecture: MWF9 (4-370) Recitation: MW1 (36-372) or MW2 (36-372) or TR10 (36-144) or TR11 (36-144) +final
______
Chemical and physical properties of the cell and its building blocks. Structures of proteins and principles of catalysis. The chemistry of organic/inorganic cofactors required for chemical transformations within the cell. Basic principles of metabolism and regulation in pathways, including glycolysis, gluconeogenesis, fatty acid synthesis/degradation, pentose phosphate pathway, Krebs cycle and oxidative phosphorylation, DNA replication, and transcription and translation.
E. Nolan, A. Klibanov
Textbooks (Fall 2016)

20.554[J] Frontiers in Chemical Biology
______

Graduate (Fall)
(Same subject as5.54[J],7.540[J])
Prereq: 5.13, 5.07, 7.06, permission of instructor
Units: 2-0-4
Lecture: R8.30-10 (4-231)
______
Introduction to current research at the interface of chemistry, biology, and bioengineering. Topics include imaging of biological processes, metabolic pathway engineering, protein engineering, mechanisms of DNA damage, RNA structure and function, macromolecular machines, protein misfolding and disease, metabolomics, and methods for analyzing signaling network dynamics. Lectures are interspersed with class discussions and student presentations based on current literature.
M. Shoulders
No textbook information available

20.560 Statistics for Biological Engineering
______

Graduate (IAP)
Prereq: Permission of instructor
Units: 2-0-2 [P/D/F]
______
Provides basic tools for analyzing experimental data, interpreting statistical reports in the literature, and reasoning under uncertain situations. Topics include probability theory, statistical tests, data exploration, Bayesian statistics, and machine learning. Emphasizes discussion and hands-on learning. Experience with MATLAB, Python, or R recommended.
S. Olesen

20.902 Independent Study in Biological Engineering
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Opportunity for independent study under regular supervision by a faculty member. Projects require prior approval, as well as a substantive paper. Minimum 12 units required.
Staff
No textbook information available

20.903 Independent Study in Biological Engineering
______

Undergrad (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Opportunity for independent study under regular supervision by a faculty member. Projects require prior approval, as well as a substantive paper. Minimum 6-12 units required.
Staff
No textbook information available

20.920 Practical Work Experience
______

Undergrad (Fall, IAP, Spring, Summer)
Prereq: None
Units: 0-1-0 [P/D/F]
TBA.
______
For Course 20 students participating in off-campus work experiences in biological engineering. Before registering for this subject, students must have an employment offer from a company or organization and must identify a BE supervisor. Upon completion of the work, student must submit a letter from the employer describing the work accomplished, along with a substantive final report from the student approved by the MIT supervisor. Subject to departmental approval. Consult departmental undergraduate office.
Staff
No textbook information available

20.950 Research Problems in Biological Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Directed research in the fields of bioengineering and environmental health. Limited to BE students.
Staff
No textbook information available

20.951 Thesis Proposal
______

Graduate (Fall, Spring, Summer)
Prereq: Permission of instructor
Units: 0-24-0 [P/D/F]
TBA.
______
Thesis proposal research and presentation to the thesis committee.
Staff
No textbook information available

20.960 Teaching Experience in Biological Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
For qualified graduate students interested in teaching. Tutorial, laboratory, or classroom teaching under the supervision of a faculty member. Enrollment limited by availability of suitable teaching assignments.
Staff
No textbook information available

20.BME Undergraduate Research in Biomedical Engineering
(New)
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Individual research project with biomedical or clinical focus, arranged with appropriate faculty member or approved supervisor. Forms and instructions for the proposal and final report are available in the BE Undergraduate Office.
Consult BE Department
No textbook information available

20.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No textbook information available

20.S900 Special Subject in Biological Engineering
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
Lecture: W9 (4-270)
______
No textbook information available

20.S940 Special Subject in Biological Engineering
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Detailed discussion of selected topics of current interest. Classwork in various areas not covered by regular subjects.
Staff
No textbook information available

20.S947-20.S949 Special Subject in Biological Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
20.S947: Lecture: F2 (56-180)
20.S948: TBA.
20.S949: TBA.
______
20.S947: No textbook information available
20.S948: No textbook information available
20.S949: No textbook information available

20.S952 Special Subject in Biological Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
Lecture: R EVE (4-6 PM) (32-141)
______
Detailed discussion of selected topics of current interest. Classwork in various areas not covered by regular subjects.
Staff
No textbook information available

20.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of an SM or PhD thesis; to be arranged by the student and the MIT faculty advisor.
Staff
Textbooks arranged individually

20.UR Undergraduate Research Opportunities
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Laboratory research in the fields of bioengineering or environmental health. May be extended over multiple terms.
S. Manalis
Textbooks arranged individually

20.URG Undergraduate Research Opportunities
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Emphasizes direct and active involvement in laboratory research in bioengineering or environmental health. May be extended over multiple terms.
Consult S. Manalis
Textbooks arranged individually


left arrow|20.00-20.ZZZZ|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 22: Nuclear Science and Engineering
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Course 22: Nuclear Science and Engineering
Fall 2016


Undergraduate Subjects

22.00 Introduction to Modeling and Simulation
______

Undergrad (Spring) Rest Elec in Sci & Tech
Engineering School-Wide Elective Subject.
(Offered under:1.021,3.021,10.333,22.00)
Prereq: 18.03, 3.016, or permission of instructor
Units: 4-0-8
______
Basic concepts of computer modeling and simulation in science and engineering. Uses techniques and software for simulation, data analysis and visualization. Continuum, mesoscale, atomistic and quantum methods used to study fundamental and applied problems in physics, chemistry, materials science, mechanics, engineering, and biology. Examples drawn from the disciplines above are used to understand or characterize complex structures and materials, and complement experimental observations.
M. Buehler, R. Taylor

22.01 Introduction to Nuclear Engineering and Ionizing Radiation
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: None
Units: 5-0-7
Lecture: TR9,F1 (24-115) Recitation: F2-4 (24-307) +final
______
Provides an introduction to nuclear science and its engineering applications. Describes basic nuclear models, radioactivity, nuclear reactions and kinematics. Covers the interaction of ionizing radiation with matter, with an emphasis on radiation detection, radiation shielding, and radiation effects on human health. Presents energy systems based on fission and fusion nuclear reactions, as well as industrial and medical applications of nuclear science.
M. Short
Textbooks (Fall 2016)

22.011 Seminar in Nuclear Science and Engineering
______

Undergrad (Fall)
Prereq: None
Units: 2-0-4
Lecture: T3-5 (24-112)
______
Surveys the range of diverse subjects in nuclear science and engineering covered by the department. Topics include quantum computing, energy and power, radiation effects-stem cells and DNA, BNCT, nuclear space applications, fusion, airport security, accelerators, magnetic resonance imaging, non-proliferation, risk assessment, safety, biology and medicine. A demonstration of the MIT Reactor as a research tool is given as well as a tour of the MIT Tokomak fusion machine and accelerators used in research.
Z. Hartwig
No textbook information available

22.012 Seminar in Fusion and Plasma Physics
______

Undergrad (Spring)
Prereq: None
Units: 2-0-4
URL: http://web.mit.edu/22.012/www/
______
Lectures and discussion introducing the range of topics relevant to plasma physics and fusion engineering. Introductory discussion of the economic and ecological motivation for the development of fusion power. Contemporary magnetic confinement schemes, theoretical questions, and engineering considerations are presented by expert guest lecturers. Includes visit to Plasma Science and Fusion Center experimental facilities.
D. Whyte

22.014 Ethics for Engineers
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.082,2.900,6.904,10.01,22.014)
Prereq: None
Units: 2-0-4
Lecture: M3-5 (66-144, 36-153) or T3-5 (37-212) or T EVE (7.30-9.30 PM) (66-144) or W3-5 (36-153)
______
Integrates classical readings that provide an overview of ethics with a survey of case studies that focus on ethical problems arising in the practice of engineering. Readings taken from a variety of sources, such as Aristotle, Machiavelli, Bacon, Hobbes, Locke, the Founding Fathers, and the Bible. Case studies include written analyses and films that address engineering disasters, biotechnology, court cases, ethical codes, and the ultimate scope and aims of engineering.
D. Doneson, B. L. Trout
No required or recommended textbooks

22.02 Introduction to Applied Nuclear Physics
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: Physics II (GIR), Calculus II (GIR); 8.03 or permission of instructor
Units: 5-0-7
______
Covers basic concepts of nuclear physics with emphasis on nuclear structure and interactions of radiation with matter. Topics include elementary quantum theory; nuclear forces; shell structure of the nucleus; alpha, beta and gamma radioactive decays; interactions of nuclear radiations (charged particles, gammas, and neutrons) with matter; nuclear reactions; fission and fusion.
P. Cappellaro

22.033 Nuclear Systems Design Project
______

Undergrad (Fall)
(Subject meets with22.33)
Prereq: None
Units: 3-0-12
Lecture: MWF11 (24-115)
______
Group design project involving integration of nuclear physics, particle transport, control, heat transfer, safety, instrumentation, materials, environmental impact, and economic optimization. Provides opportunity to synthesize knowledge acquired in nuclear and non-nuclear subjects and apply this knowledge to practical problems of current interest in nuclear applications design. Past projects have included using a fusion reactor for transmutation of nuclear waste, design and implementation of an experiment to predict and measure pebble flow in a pebble bed reactor, and development of a mission plan for a manned Mars mission including the conceptual design of a nuclear powered space propulsion system and power plant for the Mars surface, a lunar/Martian nuclear power station and the use of nuclear plants to extract oil from tar sands. Students taking graduate version complete additional assignments.
M. Short, A. White
No required or recommended textbooks

22.04[J] Social Problems of Nuclear Energy
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject asSTS.084[J])
Prereq: None
Units: 3-0-9
______
Surveys the major social challenges for nuclear energy. Topics include the ability of nuclear power to help mitigate climate change; challenges associated with ensuring nuclear safety; the effects of nuclear accidents; the management of nuclear waste; the linkages between nuclear power and nuclear weapons, the consequences of nuclear war; and political challenges to the safe and economic regulation of the nuclear industry. Weekly readings presented from both sides of the debate, followed by in-class discussions. Instruction and practice in oral and written communication provided. Limited to 18.
R. S. Kemp

22.05 Neutron Science and Reactor Physics
______

Undergrad (Fall)
Prereq: 18.03, 22.01, 22.06
Units: 5-0-7
Lecture: TR11-12.30 (24-115) Recitation: F9-11 (24-115) +final
______
Introduces fundamental properties of the neutron. Covers reactions induced by neutrons, nuclear fission, slowing down of neutrons in infinite media, diffusion theory, the few-group approximation, point kinetics, and fission-product poisoning. Emphasizes the nuclear physics bases of reactor design and its relationship to reactor engineering problems.
B. Forget
Textbooks (Fall 2016)

22.054[J] Materials Performance in Extreme Environments
______

Not offered academic year 2016-2017Undergrad (Spring)
(Same subject as3.154[J])
Prereq: 3.032, 3.044
Units: 3-2-7
______
Studies the behavior of materials in extreme environments typical of those in which advanced energy systems (including fossil, nuclear, solar, fuel cells, and battery) operate. Takes both a science and engineering approach to understanding how current materials interact with their environment under extreme conditions. Explores the role of modeling and simulation in understanding material behavior and the design of new materials. Focuses on energy and transportation related systems.
R. Ballinger

22.055 Radiation Biophysics
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with22.55[J],HST.560[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Provides a background in sources of radiation with an emphasis on terrestrial and space environments and on industrial production. Discusses experimental approaches to evaluating biological effects resulting from irradiation regimes differing in radiation type, dose and dose-rate. Effects at the molecular, cellular, organism, and population level are examined. Literature is reviewed identifying gaps in our understanding of the health effects of radiation, and responses of regulatory bodies to these gaps is discussed. Students taking graduate version complete additional assignments.
Staff

22.06 Engineering of Nuclear Systems
______

Undergrad (Spring)
Prereq: 2.005
Units: 3-0-9
______
Using the basic principles of reactor physics, thermodynamics, fluid flow and heat transfer, students examine the engineering design of nuclear power plants. Emphasizes light-water reactor technology, thermal limits in nuclear fuels, thermal-hydraulic behavior of the coolant, nuclear safety and dynamic response of nuclear power plants.
E. Baglietto

22.071[J] Electronics, Signals, and Measurement
______

Undergrad (Spring) Rest Elec in Sci & Tech
(Same subject as6.071[J])
Prereq: 18.03
Units: 3-3-6
______
Provides the knowledge necessary for reading schematics and designing, building, analyzing, and testing fundamental analog and digital circuits. Students construct interactive examples and explore the practical uses of electronics in engineering and experimental science, including signals and measurement fundamentals. Uses state-of-the-art hardware and software for data acquisition, analysis, and control. Suitable for students with little or no previous background in electronics.
A. White

22.081[J] Introduction to Sustainable Energy
______

Undergrad (Fall)
(Same subject as2.650[J],10.291[J])
(Subject meets with1.818[J],2.65[J],10.391[J],11.371[J],22.811[J])
Prereq: Permission of instructor
Units: 3-1-8
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various renewable and conventional energy production technologies, energy end-use practices and alternatives, and consumption practices in different countries. Investigates their attributes within a quantitative analytical framework for evaluation of energy technology system proposals. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments. Limited to juniors and seniors.
M. W. Golay
Textbooks (Fall 2016)

22.09 Principles of Nuclear Radiation Measurement and Protection
______

Undergrad (Fall) Institute Lab
(Subject meets with22.90)
Prereq: 22.01
Units: 2-6-4
Lecture: M1-3 (NW12-222) Lab: W12-3 (NW12-222) or F12-3 (NW12-222)
______
Combines lectures, demonstrations, and experiments. Review of radiation protection procedures and regulations; theory and use of alpha, beta, gamma, and neutron detectors; applications in imaging and dosimetry; gamma-ray spectroscopy; design and operation of automated data acquisition experiments using virtual instruments. Meets with graduate subject 22.90, but homework assignments and examinations differ. Instruction and practice in written communication provided.
A. Danagoulian, G. Kohse
No textbook information available

22.091, 22.093 Independent Project in Nuclear Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
22.091: TBA.
22.093: TBA.
______
For undergraduates who wish to conduct a one-term project of theoretical or experimental nature in the field of nuclear engineering, in close cooperation with individual staff members. Topics and hours arranged to fit students' requirements. Projects require prior approval by the Course 22 Undergraduate Office. 22.093 is graded P/D/F.
M. Short
22.091: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
22.093: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

22.S092-22.S094 Special Subject in Nuclear Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
22.S092: TBA.
22.S093: TBA.
22.S094: TBA.
______
Seminar or lecture on a topic in nuclear science and engineering that is not covered in the regular curriculum.
M. Short
22.S092: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
22.S093: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
22.S094: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

22.EPE UPOP Engineering Practice Experience
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.EPE,2.EPE,3.EPE,6.EPE,10.EPE,16.EPE,22.EPE)
Prereq: 2.EPW or permission of instructor
Units: 0-0-1 [P/D/F]
TBA.
______
Provides sophomores with guided practice in finding opportunities and excelling in the world of practice. Building on the skills and relationships acquired in the Engineering Practice Workshop, students receive coaching to articulate goals, invoke the UPOP network of mentors and employers, identify and pursue opportunities and negotiate terms of their summer assignment. Students complete a 10-12 week internship, which includes filing three progress reports, conducting one informational interview, and possibly hosting a site visit by MIT staff. Returning to campus as juniors, UPOP students take part in reflective exercises that aid assimilation of learning objectives and reinforce the cognitive link between all aspects of the UPOP experience and disciplinary fields of study. Sequence begins in the spring of sophomore year and ends in the fall of junior year.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

22.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No required or recommended textbooks

22.THT Undergraduate Thesis Tutorial
______

Undergrad (Fall)
Prereq: None
Units: 1-0-2 [P/D/F]
Lecture: F3 (24-121)
______
A series of lectures on prospectus and thesis writing. Students select a thesis topic and a thesis advisor who reviews and approves the prospectus for thesis work in the spring term.
R. Lester, B. Yildiz
No required or recommended textbooks

22.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 22.THT
Units arranged
TBA.
______
Program of research, leading to the writing of an SB thesis, to be arranged by the student and appropriate MIT faculty member. See department undergraduate headquarters.
M. Short
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

22.UR Undergraduate Research Opportunities Program
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

22.URG Undergraduate Research Opportunities Program
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
The Undergraduate Research Opportunities Program is an excellent way for undergraduate students to become familiar with the department of Nuclear Science and Engineering. Student research as a UROP project has been conducted in areas of fission reactor studies, utilization of fusion devices, applied radiation physics research, and biomedical applications. Projects include the study of engineering aspects for fusion and fission energy sources, and utilization of radiations.
M. Short
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|22.00-22.099 plus UROP, UPOP, and ThU|22.101-22.599|22.60-22.THG|right arrow



Produced: 26-SEP-2016 05:10 PMFall 2016 Course 22: Nuclear Science and Engineering
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Course 22: Nuclear Science and Engineering
Fall 2016


Graduate Subjects

22.107 Computational Nuclear Science and Engineering
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 18.085, 22.00, or permission of instructor
Units: 3-0-9
______
Develops practical scientific computing skills with applications in radiation physics, reactor engineering and design, nuclear materials, fusion, etc. Topics include compiling/profiling/time and memory complexities/debugging, solvers of ordinary differential equations and partial differential equations, error versus stability, and pre-and post-processing. Includes a survey of visualization and parallel computing and case studies in quantum mechanics, neutron diffusion and transport, simple CFD, and radiation cascade simulations. Assignments require programming in one or several languages of choice; some MATLAB-free assignments also required.
J. Li

22.11 Applied Nuclear Physics
______

Graduate (Fall) Can be repeated for credit; first half of term
Prereq: 22.02 or permission of instructor
Units: 2-0-4
Ends Oct 21. Lecture: TR9.30-11 (24-121)
______
Introduction to nuclear structure, reactions, and radioactivity. Review of quantization, the wave function, angular momentum and tunneling. Simplified application to qualitative understanding of nuclear structure. Stable and unstable isotopes, radioactive decay, decay products and chains. Nuclear reactions, cross-sections, and fundamental forces, and the resulting phenomena.
B. Yildiz
Textbooks (Fall 2016)

22.12 Radiation Interactions, Control, and Measurement
______

Graduate (Fall) Can be repeated for credit; second half of term
Prereq: 8.02 or permission of instructor
Units: 2-0-4
Begins Oct 24. Lecture: TR9.30-11 (24-121) +final
______
The interaction, attenuation, and biological effects of penetrating radiation, especially neutrons and photons. Physical processes of radiation scattering and absorption, and their cross-sections. Outline of health physics. Biological effects of radiation, and its quantification. Principles of radiation shielding, detection, dosimetry and radiation protection.
A. Danagoulian
No textbook information available

22.13 Nuclear Energy Systems
______

Graduate (Spring) Can be repeated for credit; first half of term
Prereq: 22.01, 2.005, or permission of instructor
Units: 2-0-4
______
Introduction to generation of energy from nuclear reactions. Characteristics of nuclear energy. Fission cross-sections, criticality, and reaction control. Basic considerations of fission reactor engineering, thermal hydraulics, and safety. Nuclear fuel and waste characteristics. Fusion reactions and the character and conditions of energy generation. Plasma physics and approaches to achieving terrestrial thermonuclear fusion energy.
B. Forget

22.14 Materials in Nuclear Engineering
______

Graduate (Spring) Can be repeated for credit; first half of term
Prereq: Chemistry (GIR) or permission of instructor
Units: 2-0-4
______
Introduces the fundamental phenomena of materials science with special attention to radiation and harsh environments. Materials lattices and defects and the consequent understanding of strength of materials, fatigue, cracking, and corrosion. Coulomb collisions of charged particles; their effects on structured materials; damage and defect production, knock-ons, transmutation, cascades and swelling. Materials in fission and fusion applications: cladding, waste, plasma-facing components, blankets.
J. Li

22.15 Essential Numerical Methods
______

Graduate (Fall) Can be repeated for credit; first half of term
Prereq: 12.010 or permission of instructor
Units: 2-0-4
Ends Oct 28. Lecture: MW9.30-11 (24-115) Recitation: MW9-9.30 (24-115)
______
Introduces computational methods for solving physical problems in nuclear applications. Ordinary and partial differential equations for particle orbit, and fluid, field, and particle conservation problems; their representation and solution by finite difference numerical approximations. Iterative matrix inversion methods. Stability, convergence, accuracy and statistics. Particle representations of Boltzmann's equation and methods of solution such as Monte-Carlo and particle-in-cell techniques.
N. Louriero
Textbooks (Fall 2016)

22.16 Nuclear Technology and Society
______

Graduate (Spring) Can be repeated for credit; second half of term
Prereq: 22.01 or permission of instructor
Units: 2-0-4
______
Introduces the societal context and challenges for nuclear technology. Major themes include economics and valuation of nuclear power, interactions with government and regulatory frameworks; safety, quantification of radiation hazards, and public attitudes to risk. Covers policies and methods for limiting nuclear-weapons proliferation, including nuclear detection, materials security and fuel-cycle policy.
R. S. Kemp

Nuclear Reactor Physics

22.211 Nuclear Reactor Physics I
______

Graduate (Spring)
Prereq: 22.05
Units: 3-0-9
______
Provides an overview of reactor physics methods for core design and analysis. Topics include nuclear data, neutron slowing down, homogeneous and heterogeneous resonance absorption, calculation of neutron spectra, determination of group constants, nodal diffusion methods, Monte Carlo simulations of reactor core reload design methods.
K. Smith

22.212 Nuclear Reactor Analysis II
______

Graduate (Fall)
Prereq: 22.211
Units: 3-2-7
Lecture: MW1-2.30 (24-115)
______
Addresses advanced topics in nuclear reactor physics with an additional focus towards computational methods and algorithms for neutron transport. Covers current methods employed in lattice physics calculations, such as resonance models, critical spectrum adjustments, advanced homogenization techniques, fine mesh transport theory models, and depletion solvers. Also presents deterministic transport approximation techniques, such as the method of characteristics, discrete ordinates methods, and response matrix methods.
K. Smith
No textbook information available

22.213 Nuclear Reactor Physics III
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 22.211
Units: 3-0-9
______
Covers numerous high-level topics in nuclear reactor analysis methods and builds on the student's background in reactor physics to develop a deep understanding of concepts needed for time-dependent nuclear reactor core physics, including coupled non-linear feedback effects. Introduces numerical algorithms needed to solve real-world time-dependent reactor physics problems in both diffusion and transport. Additional topics include iterative numerical solution methods (e.g., CG, GMRES, JFNK, MG), nonlinear accelerator methods, and numerous modern time-integration techniques.
K. Smith, B. Forget

22.251 Systems Analysis of the Nuclear Fuel Cycle
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 22.05
Units: 3-2-7
Lecture: TR1-2.30 (24-115)
______
Study of the relationship between the technical and policy elements of the nuclear fuel cycle. Topics include uranium supply, enrichment, fuel fabrication, in-core reactivity and fuel management of uranium and other fuel types, used fuel reprocessing and waste disposal. Principles of fuel cycle economics and the applied reactor physics of both contemporary and proposed thermal and fast reactors are presented. Nonproliferation aspects, disposal of excess weapons plutonium, and transmutation of long lived radioisotopes in spent fuel are examined. Several state-of-the-art computer programs relevant to reactor core physics and heat transfer are provided for student use in problem sets and term papers.
C. Forsberg
No textbook information available

Nuclear Reactor Engineering

22.312 Engineering of Nuclear Reactors
______

Graduate (Spring)
Prereq: 2.001, 2.005; or permission of instructor
Units: 3-0-9
______
Engineering principles of nuclear reactors, emphasizing power reactors. Power plant thermodynamics, reactor heat generation and removal (single-phase as well as two-phase coolant flow and heat transfer), and structural mechanics. Engineering considerations in reactor design.
J. Buongiorno

22.313[J] Thermal Hydraulics in Power Technology
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as 2.59[J],10.536[J])
Prereq: 2.006, 10.302, 22.312, or permission of instructor
Units: 3-2-7
______
Emphasis on thermo-fluid dynamic phenomena and analysis methods for conventional and nuclear power stations. Kinematics and dynamics of two-phase flows. Steam separation. Boiling, instabilities, and critical conditions. Single-channel transient analysis. Multiple channels connected at plena. Loop analysis including single and two-phase natural circulation. Subchannel analysis.
E. Baglietto

22.314[J] Structural Mechanics in Nuclear Power Technology
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as1.56[J],2.084[J])
Prereq: 2.001 or permission of instructor
Units: 3-0-9
______
Structural components in nuclear power plant systems, their functional purposes, operating conditions, and mechanical/structural design requirements. Combines mechanics techniques with models of material behavior to determine adequacy of component design. Considerations include mechanical loading, brittle fracture, inelastic behavior, elevated temperatures, neutron irradiation, vibrations and seismic effects.
Staff

22.315 Applied Computational Fluid Dynamics and Heat Transfer
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Focuses on the application of computational fluid dynamics to the analysis of power generation and propulsion systems, and on industrial and chemical processes in general. Discusses simulation methods for single and multiphase applications and their advantages and limitations in industrial situations. Students practice breaking down an industrial problem into its modeling challenges, designing and implementing a plan to optimize and validate the modeling approach, performing the analysis, and quantifying the uncertainty margin.
E. Baglietto

22.33 Nuclear Engineering Design
______

Graduate (Fall)
(Subject meets with22.033)
Prereq: 22.312
Units: 3-0-15
Lecture: MWF11 (24-115)
______
Group design project involving integration of nuclear physics, particle transport, control, heat transfer, safety, instrumentation, materials, environmental impact, and economic optimization. Provides opportunity to synthesize knowledge acquired in nuclear and non-nuclear subjects and apply this knowledge to practical problems of current interest in nuclear applications design. Past projects have included using a fusion reactor for transmutation of nuclear waste, design and implementation of an experiment to predict and measure pebble flow in a pebble bed reactor, and development of a mission plan for a manned Mars mission including the conceptual design of a nuclear powered space propulsion system and power plant for the Mars surface. Students taking graduate version complete additional assignments.
M. Short, A. White
No textbook information available

22.38 Probability and Its Applications To Reliability, Quality Control, and Risk Assessment
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Interpretations of the concept of probability. Basic probability rules; random variables and distribution functions; functions of random variables. Applications to quality control and the reliability assessment of mechanical/electrical components, as well as simple structures and redundant systems. Elements of statistics. Bayesian methods in engineering. Methods for reliability and risk assessment of complex systems, (event-tree and fault-tree analysis, common-cause failures, human reliability models). Uncertainty propagation in complex systems (Monte Carlo methods, Latin hypercube sampling). Introduction to Markov models. Examples and applications from nuclear and other industries, waste repositories, and mechanical systems. Open to qualified undergraduates.
M. W. Golay

22.39 Integration of Reactor Design, Operations, and Safety
______

Graduate (Fall)
Prereq: 22.211, 22.312
Units: 3-2-7
Lecture: TR2.30-4 (24-115)
______
Integration of reactor physics and engineering sciences into nuclear power plant design focusing on designs that are projected to be used in the first half of this century. Topics include materials issues in plant design and operations, aspects of thermal design, fuel depletion and fission-product poisoning, and temperature effects on reactivity. Safety considerations in regulations and operations such as the evolution of the regulatory process, the concept of defense in depth, general design criteria, accident analysis, probabilistic risk assessment, and risk-informed regulations.
R. Ballinger
No textbook information available

22.40[J] Fundamentals of Advanced Energy Conversion
______

Graduate (Spring)
(Same subject as2.62[J],10.392[J])
(Subject meets with2.60[J],10.390[J])
Prereq: 2.006, or 2.051 and 2.06, or permission of instructor
Units: 4-0-8
______
Fundamentals of thermodynamics, chemistry, and transport applied to energy systems. Analysis of energy conversion and storage in thermal, mechanical, chemical, and electrochemical processes in power and transportation systems, with emphasis on efficiency, performance and environmental impact. Applications to fuel reforming and alternative fuels, hydrogen, fuel cells and batteries, combustion, catalysis, combined and hybrid power cycles using fossil, nuclear and renewable resources. CO2 separation and capture. Biomass energy. Meets with 2.60 when offered concurrently; students taking the graduate version complete additional assignments.
A. F. Ghoniem, W. Green

Radiation Interactions and Applications

22.51 Quantum Theory of Radiation Interactions
______

Graduate (Fall)
Prereq: 22.11
Units: 3-0-9
Lecture: MW11-12.30 (24-121)
______
Introduces elements of applied quantum mechanics and statistical physics. Starting from the experimental foundation of quantum mechanics, develops the basic principles of interaction of electromagnetic radiation with matter. Introduces quantum theory of radiation, time-dependent perturbation theory, transition probabilities and cross sections. Applications are to controlling coherent and decoherent dynamics with examples from quantum information processing.
P. Cappellaro
No required or recommended textbooks

22.55[J] Radiation Biophysics
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject asHST.560[J])
(Subject meets with22.055)
Prereq: Permission of instructor
Units: 3-0-9
______
Provides a background in sources of radiation with an emphasis on terrestrial and space environments and on industrial production. Discusses experimental approaches to evaluating biological effects resulting from irradiation regimes differing in radiation type, dose and dose-rate. Effects at the molecular, cellular, organism, and population level are examined. Literature is reviewed identifying gaps in our understanding of the health effects of radiation, and responses of regulatory bodies to these gaps is discussed. Students taking graduate version complete additional assignments.
Staff

22.56[J] Noninvasive Imaging in Biology and Medicine
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as9.173[J],20.483[J],HST.561[J])
Prereq: 18.03, 8.03, or permission of instructor
Units: 3-0-9
______
Background in the theory and application of noninvasive imaging methods in biology and medicine, with emphasis on neuroimaging. Focuses on the modalities most frequently used in scientific research (x-ray CT, PET/SPECT, MRI, and optical imaging), and includes discussion of molecular imaging approaches used in conjunction with these scanning methods. Lectures are supplemented by in-class discussions of problems in research and demonstrations of imaging systems.
A. Jasanoff

22.561[J] Magnetic Resonance Analytic, Biochemical, and Imaging Techniques
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject asHST.584[J])
Prereq: Permission of instructor
Units: 3-0-12
______
Introduction to basic NMR theory. Examples of biochemical data obtained using NMR summarized along with other related experiments. Detailed study of NMR imaging techniques includes discussions of basic cross-sectional image reconstruction, image contrast, flow and real-time imaging, and hardware design considerations. Exposure to laboratory NMR spectroscopic and imaging equipment included.
L. Wald, K. Setsompop

22.562 Spatial Aspects of Nuclear Magnetic Resonance Spectroscopy
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 18.03, 8.05
Units: 3-0-9
______
Discusses the theory and application of nuclear magnetic resonance spectroscopy to questions of the spatial distribution of spins. Covers NMR imaging, localized spectroscopy, and local geometries as determined by diffusive processes. The theory is discussed in terms of the density operator and reciprocal space (for both imaging and motional studies). Describes applications to rapid imaging, dynamic imaging, microscopy, and localized spectroscopy. Instrumentation and experimental constraints are also described.
Staff


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Produced: 26-SEP-2016 05:10 PMFall 2016 Course 22: Nuclear Science and Engineering
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Course 22: Nuclear Science and Engineering
Fall 2016


Plasmas and Controlled Fusion

22.611[J] Introduction to Plasma Physics I
______

Graduate (Fall)
(Same subject as8.613[J])
Prereq: 6.013 or 8.07; 18.04 orCoreq: 18.075
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR11-12.30 (NW16-213)
______
Introduces plasma phenomena relevant to energy generation by controlled thermonuclear fusion and to astrophysics. Elementary plasma concepts, plasma characterization. Motion of charged particles in magnetic fields. Coulomb collisions, relaxation times, transport processes. Two-fluid hydrodynamic and MHD descriptions. Plasma confinement by magnetic fields, simple equilibrium and stability analysis. Wave propagation in a magnetic field; application to RF plasma heating. Introduction to kinetic theory; Vlasov, Boltzmann and Fokker-Planck equations; relation of fluid and kinetic descriptions. Electron and ion acoustic plasma waves, Landau damping.
A. White
Textbooks (Fall 2016)

22.612[J] Introduction to Plasma Physics II
______

Graduate (Spring)
(Same subject as8.614[J])
Prereq: 6.651J, 8.613J, or 22.611J
Units: 3-0-9
______
Linear waves and instabilities in magnetized plasma; solutions of Vlasov-Maxwell equations in homogeneous and inhomogeneous plasmas; conservation principles for energy and momentum; quasi-linear theory and nonlinear stabilization; solitons and coherent nonlinear phenomena; collisions and discrete particle effects; fluctuations in a stable plasma; Fokker-Planck equation and transport phenomena. A subject description tailored to fit the background and interests of the attending students distributed shortly before and at the beginning of the subject.
Staff

22.615 MHD Theory of Fusion Systems
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 22.611J, 6.651J, or 8.613J
Units: 3-0-9
______
Discussion of MHD equilibria in cylindrical, toroidal, and noncircular configurations. MHD stability theory including the Energy Principle, interchange instability, ballooning modes, second region of stability, and external kink modes. Description of current configurations of fusion interest.
N. Louriero

22.616 Plasma Transport Theory
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 22.615
Units: 3-0-9
______
The Fokker-Planck operator for Coulomb collisions, including the Landau and Rosenbluth potential forms, is derived, expanded to obtain useful limits, and used to define characteristic times. Classical collisional transport in an arbitrary magnetic field is developed first, and then the high (Pfirsch-Schluter), low (banana), and intermediate (plateau) collisionality regimes of tokamak transport are examined with emphasis on the banana regime where bootstrap current is most pronounced. Gyrokinetics and zonal flow is discussed.
Staff

22.617 Plasma Turbulence and Transport
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 22.616 or permission of instructor
Units: 3-0-9
______
Introduces plasma turbulence and turbulent transport, with a focus on fusion plasmas. Covers theory of mechanisms for turbulence in confined plasmas, fluid and kinetic equations, and linear and nonlinear gyrokinetic equations; transport due to stochastic magnetic fields, magnetohydrodynamic (MHD) turbulence, and drift wave turbulence; and suppression of turbulence, structure formation, intermittency, and stability thresholds. Emphasis on comparing experiment and theory. Discusses experimental techniques, simulations of plasma turbulence, and predictive turbulence-transport models.
Staff

22.62 Fusion Energy
______

Graduate (Spring)
Prereq: 22.611
Units: 3-0-9
______
Basic nuclear physics and plasma physics for controlled fusion. Fusion cross sections and consequent conditions required for ignition and energy production. Principles of magnetic and inertial confinement. Description of magnetic confinement devices: tokamaks, stellarators and RFPs, their design and operation. Elementary plasma stability considerations and the limits imposed. Plasma heating by neutral beams and RF. Outline design of the ITER "burning plasma" experiment and a magnetic confinement reactor.
J. Freidberg

22.63 Engineering Principles for Fusion Reactors
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Fusion reactor design considerations: ignition devices, engineering test facilities, and safety/environmental concerns. Magnet principles: resistive and superconducting magnets; cryogenic features. Blanket and first wall design: liquid and solid breeders, heat removal, and structural considerations. Heating devices: radio frequency and neutral beam.
D. Whyte

22.67 Principles of Plasma Diagnostics
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.651J, 8.613J, or 22.611J
Units: 3-0-9
______
Introduction to the physical processes used to measure the properties of plasmas, especially fusion plasmas. Measurements of magnetic and electric fields, particle flux, refractive index, emission and scattering of electromagnetic waves and heavy particles; their use to deduce plasma parameters such as particle density, pressure, temperature, and velocity, and hence the plasma confinement properties. Discussion of practical examples and assessments of the accuracy and reliability of different techniques.
I. Hutchinson

Nuclear Materials

22.71[J] Modern Physical Metallurgy
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as3.40[J])
(Subject meets with3.14)
Prereq: 3.022, 3.032
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Examines how the presence of 1-, 2- and 3-D defects and second phases control the mechanical, electromagnetic and chemical behavior of metals and alloys. Considers point, line and interfacial defects in the context of structural transformations including annealing, spinodal decomposition, nucleation, growth, and particle coarsening. Concentrates on structure-function relationships, and in particular how grain size, interstitial and substitutional solid solutions, and second-phase particles impact mechanical and other properties Industrially relevant case studies illustrate lecture concepts. Students taking the graduate version explore the subject in greater depth.
C. Tasan

22.72[J] Corrosion: The Environmental Degradation of Materials
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as3.54[J])
Prereq: 3.012
Units: 3-0-9
______
Applies thermodynamics and kinetics of electrode reactions to aqueous corrosion of metals and alloys. Application of advanced computational and modeling techniques to evaluation of materials selection and susceptibility of metal/alloy systems to environmental degradation in aqueous systems. Discusses materials degradation problems in marine environments, oil and gas production, and energy conversion and generation systems, including fossil and nuclear.
R. G. Ballinger

22.73[J] Defects in Materials
(New)
______

Graduate (Fall)
(Same subject as3.33[J])
Prereq: 3.21, 3.22
Units: 3-0-9
Lecture: F11-12.30 (24-121) Recitation: F EVE (4.30-6 PM) (24-115) +final
______
Examines point, line, and planar defects in structural and functional materials. Relates their properties to transport, radiation response, phase transformations, semiconductor device performance and quantum information processing. Focuses on atomic and electronic structures of defects in crystals, with special attention to optical properties, dislocation dynamics, fracture, and charged defects population and diffusion. Examples also drawn from other systems, e.g., disclinations in liquid crystals, domain walls in ferromagnets, shear bands in metallic glass, etc.
J. Li
No textbook information available

22.74[J] Radiation Damage and Effects in Nuclear Materials
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as3.31[J])
Prereq: 22.14, 3.21, or permission of instructors
Units: 3-0-9
______
Studies the origins and effects of radiation damage in structural materials for nuclear applications. Radiation damage topics include formation of point defects, defect diffusion, defect reaction kinetics and accumulation, and differences in defect microstructures due to the type of radiation (ion, proton, neutron). Radiation effects topics include detrimental changes to mechanical properties, phase stability, corrosion properties, and differences in fission and fusion systems. Term project required.
M. Short

22.76 Nuclear Chemical Engineering
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/22.76/www/
______
Application of chemical engineering to nuclear fission reactors and nuclear waste reprocessing. Review of chemical kinetics, equilibrium, and thermodynamics. Chemistry of inorganic elements used in nuclear technology. Principles of chemical separation of radioactive waste. Examination of separation engineering processes. Isotopic enrichment techniques and processes. Chemical behavior of stable elements and radionuclides in reactor conditions. Laboratory demonstration of radioisotope separations.
Staff

22.78 Principles of Nuclear Chemical Engineering and Waste Management
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces scientific and engineering aspects of chemical engineering and waste management applied to reactors and the fuel cycle. Includes chemical behavior in reactors (normal and accident), spent nuclear fuel aging, separation processes in reprocessing, and waste treatment processes. Addresses management of radioactive wastes, including waste forms, classification, fundamental principles, governing equations for radionuclide transport in the environment, performance assessment of geological waste disposal systems, and implications of advanced fuel cycles.
C. Forsberg

Systems, Policy, and Economics

22.811[J] Sustainable Energy
______

Graduate (Fall)
(Same subject as1.818[J],2.65[J],10.391[J],11.371[J])
(Subject meets with2.650[J],10.291[J],22.081[J])
Prereq: Permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/10.391J/www/
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various energy technologies in each fuel cycle stage for fossil (oil, gas, synthetic), nuclear (fission and fusion) and renewable (solar, biomass, wind, hydro, and geothermal) energy types, along with storage, transmission, and conservation issues. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments.
M. W. Golay
Textbooks (Fall 2016)

22.812 Managing Nuclear Technology
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Examines current economic, management, and policy issues concerning nuclear power and its fuel cycle. Introduces methods for analyzing private and public policy alternatives, including techniques in economic and financial analysis. Application to specific problem areas, including nuclear waste management, weapons proliferation, and the economic competitiveness of nuclear power. Other topics include deregulation and restructuring in the electric power industry.
R. K. Lester

22.813[J] Energy Technology and Policy: From Principles to Practice
______

Graduate (Spring)
(Same subject as5.00[J],6.929[J],10.579[J])
Prereq: None
Units: 3-0-6
______
Develops analytical skills to lead a successful technology implementation with an integrated approach that combines technical, economical and social perspectives. Considers corporate and government viewpoints as well as international aspects, such as nuclear weapons proliferation and global climate issues. Discusses technologies such as oil and gas, nuclear, solar, and energy efficiency. Limited to 100.
J. Deutch

22.814 Nuclear Non-Proliferation
______

Graduate (Spring)
Prereq: None
Units: 4-0-8
______
Examines the historical development of nuclear weapons, the policies and technical strategies currently in place to secure and control the movement of nuclear materials, and the short- and long-term effects of weapons utilized under different scenarios. Considers issues such as how to restrict the global proliferation of nuclear weapons, whether nuclear energy can be made proliferation-proof and what has changed in the wake of the Cold War, as well as lessons to be learned from past experience. Emphasizes advanced approaches to both production and detection of nuclear materials.
R. S. Kemp, A. Danagoulian

General

22.90 Nuclear Science and Engineering Laboratory
______

Graduate (Fall)
(Subject meets with22.09)
Prereq: permission of instructor
Units: 2-6-4
Lecture: M1-3 (NW12-222) Lab: W12-3 (NW12-222) or F12-3 (NW12-222)
______
See description under subject 22.09.
A. Danagoulian, G. Kohse
No textbook information available

22.901 Independent Project in Nuclear Science and Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
For graduate students who wish to conduct a one-term project of theoretical or experimental nature in the field of nuclear engineering, in close cooperation with individual staff members. Topics and hours arranged to fit students' requirements. Projects require prior approval.
J. Li
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

22.911 Seminar in Nuclear Science and Engineering
______

Graduate (Fall) Can be repeated for credit
Prereq: None
Units: 2-0-1 [P/D/F]
Lecture: W12.30-2.30 (24-121) or W EVE (4-6 PM) (24-115)
______
No required or recommended textbooks

22.912 Seminar in Nuclear Science and Engineering
______

Graduate (Spring) Can be repeated for credit
Prereq: None
Units: 2-0-1 [P/D/F]
______
Restricted to graduate students engaged in doctoral thesis research.
C. Forsberg, I. Hutchinson, P. Cappellaro

22.921 Nuclear Power Plant Dynamics and Control
______

Graduate (IAP)
Prereq: None
Units: 1-0-2
______
Introduction to reactor dynamics, including subcritical multiplication, critical operation in absence of thermal feedback effects and effects of xenon, fuel and moderator temperature, etc. Derivation of point kinetics and dynamic period equations. Techniques for reactor control including signal validation, supervisory algorithms, model-based trajectory tracking, and rule-based control. Overview of light-water reactor start-up. Lectures and demonstrations with use of the MIT Research Reactor. Open to undergraduates with permission of instructor.
J. A. Bernard

22.93 Teaching Experience in Nuclear Science & Engineering
______

Graduate (Fall, Spring, Summer)
Prereq: Permission of department
Units arranged
TBA.
______
For qualified graduate students interested in teaching as a career. Classroom, laboratory, or tutorial teaching under the supervision of a faculty member. Students selected by interview. Credits for this subject may not be used toward master's or engineer's degrees. Enrollment limited by availability of suitable teaching assignments.
D. Whyte
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

22.94 Research in Nuclear Science and Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of research supervisor
Units arranged [P/D/F]
TBA.
______
For research assistants in Nuclear Science and Engineering who have not completed the NSE doctoral qualifying exam. Hours arranged with and approved by the research supervisor. Units may not be used towards advanced degree requirements.
J. Li
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

22.S902-22.S905 Special Subject in Nuclear Science and Engineering
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
22.S902: TBA.
22.S903: TBA.
22.S904: TBA.
22.S905: TBA.
______
Seminar or lecture on a topic in nuclear science and engineering that is not covered in the regular curriculum. 22.S905 is graded P/D/F.
J. Li
22.S902: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
22.S903: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
22.S904: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
22.S905: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

22.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research, leading to the writing of an SM, NE, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member. Consult department graduate office.
J. Li
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


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Produced: 26-SEP-2016 05:10 PMFall 2016 Course 1: Civil and Environmental Engineering
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Course 1: Civil and Environmental Engineering
Fall 2016


Fundamentals

1.00 Engineering Computation and Data Science
______

Undergrad (Spring) Rest Elec in Sci & Tech
(Subject meets with1.001)
Prereq: Calculus I (GIR)
Units: 5-1-6
______

1.000 Computer Programming for Scientific and Engineering Applications
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: None.Coreq: 18.03
Units: 3-2-7
Lecture: MWF3-4.30 (5-233) Lab: TBA +final
______
Presents the fundamentals of computing and computer programming (procedural and object-oriented programming) in an engineering context. Introduces logical operations, floating-point arithmetic, data structures, induction, iteration, and recursion. Computational methods for interpolation, regression, root finding, sorting, searching, and the solution of linear systems of equations and ordinary differential equations. Control of sensors and visualization of scientific data. Draws examples from engineering and scientific applications. Students use the MATLAB programming environment to complete weekly assignments.
R. Juanes
No textbook information available

1.001 Engineering Computation and Data Science
______

Graduate (Spring)
(Subject meets with1.00)
Prereq: Calculus I (GIR)
Units: 5-1-6
______
Presents fundamentals of computing and programming in an engineering context with an emphasis on data science. Introduces basics of web computing, data structures, and techniques for data analysis. Includes filtering, linear regression, simple machine learning (clustering and classifiers), and visualization. Surveys techniques for ingesting, processing, analyzing, and visualizing engineering data from a range of fields, including geo-spatial, environment, infrastructure, city dynamics, and numerical experiments. Students use JavaScript and HTML5 programming language to complete weekly assignments. Students taking graduate version complete additional assignments.
J. Williams

1.007 Big Engineering: Small Solutions with a Large Impact
______

Undergrad (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Provides a practical introduction to key topics, current research and innovative methods in the diverse field of civil and environmental engineering. Discusses career opportunities, innovation, and entrepreneurship. Under faculty supervision, students work on projects in areas such as renewable energy, sustainable design, food security, climate change, and transportation. Projects focus on design of novel solutions to grand challenges related to infrastructure, systems and the environment, and include elements of the different areas to demonstrate the interconnectedness of the discipline. Preference to first-year students and Course 1 sophomores.
B. Marelli

1.010 Uncertainty in Engineering
______

Undergrad (Fall)
Prereq: Calculus II (GIR)
Units: 5-0-7
Lecture: TR9.30-11 (1-242) Recitation: F9-11 (1-242) +final
______
Introduces probability and statistics with an emphasis on understanding, quantifying, and modeling uncertainty. Topics include events and their probability, the total probability and Bayes' theorems, discrete and continuous random variables and vectors, covariance, correlations, and conditional analysis. Random sampling, estimation of distribution parameters (method of moments, maximum likelihood, Bayesian estimation), and simple and multiple linear regression. Concepts illustrated with examples from various areas of engineering and everyday life. Integrates applications with statistical computing and graphics.
S. Saavedra
Textbooks (Fall 2016)

1.011 Project Evaluation and Management
______

Undergrad (Spring)
Prereq: None
Units: 3-1-8
______
Develops skills to evaluate a project or program using economic, environmental, and equity metrics, and to plan, execute and manage its progress to completion. Introduces students to engineering projects that are typically large-scale and long-lived, and involve many economic, financial, social and environmental factors. Covers net present value analysis, life-cycle costing, and benefit-cost analysis. Culminates in a term project in which small teams study a historical or prospective project of their choosing. Instruction and practice in oral and written communication provided.
J. Sussman

1.013 Senior Civil and Environmental Engineering Design
______

Undergrad (Spring)
Prereq: Permission of instructor
Units: 2-6-4
______
Students engage with faculty around a topic of mutual interest, building on the knowledge/skills gained throughout their program. Synthesizes prior coursework and experiences through a semester-long design project and related assignments. Students form teams to work on projects of their choosing, focusing in depth on the diverse areas within civil and environmental engineering. Teams demonstrate creativity in applying theories and methodologies while considering their project's technical, environmental and social feasibility. Includes lectures on a variety of related engineering concepts, as well as scholarship and engineering practice and ethics. Provides instruction and practice in oral and written communication.
H. Hemond

1.015[J] Design of Electromechanical Robotic Systems
______

Undergrad (Spring) 1/2 Institute Lab
(Same subject as2.017[J])
Prereq: 2.003 or 2.03;Coreq: 2.005, 2.05 and 2.051, or 2.016; 2.671
Units: 3-3-6
______
Design, construction, and testing of field robotic systems, through team projects with each student responsible for a specific subsystem. Projects focus on electronics, instrumentation, and machine elements. Design for operation in uncertain conditions is a focus point, with ocean waves and marine structures as a central theme. Basic statistics, linear systems, Fourier transforms, random processes, spectra and extreme events with applications in design. Lectures on ethics in engineering practice included. Enrollment may be limited due to laboratory capacity.
F. S. Hover, J. J. Leonard

1.016 Design for Complex Environmental Issues: Building Solutions and Communicating Ideas
______

Undergrad (Spring)
Prereq: None
Units: 3-1-5
______
Students work in small groups, under the guidance of researchers from MIT, to pursue specific aspects of the year's Terrascope problem. Teams design and build prototypes, graphic displays and other tools to communicate their findings and display them in a Bazaar of Ideas open to the MIT community. Some teams develop particular solutions, others work to provide deeper understanding of the issues, and others focus on ways to communicate these ideas with the general public. Students' work is evaluated by independent experts. Offers students an opportunity to develop ideas from the fall semester and to work in labs across MIT. Limited to first-year students.
C. Harvey

1.018A[J] Fundamentals of Ecology I
______

Undergrad (Fall); first half of term
(Same subject as7.30A[J],12.031A[J])
Prereq: None
Units: 2-0-4
Ends Oct 21. Lecture: TR11-12.30 (48-316) Recitation: M4 (48-316) or R4 (48-308)
______
Fundamentals of ecology, considering Earth as an integrated dynamic living system. Coevolution of the biosphere and geosphere, biogeochemical cycles, metabolic diversity, primary productivity, competition and the niche, trophic dynamics and food webs, population growth and limiting factors. Combination of 1.018A and 1.018B counts as REST subject.
O. Cordero, M. Follows
Textbooks (Fall 2016)

1.018B[J] Fundamentals of Ecology II
______

Undergrad (Fall); second half of term
(Same subject as7.30B[J],12.031B[J])
Prereq: 1.018A
Units: 2-0-4
Begins Oct 24. Lecture: TR11-12.30 (48-316) Recitation: M4 (48-316) or R4 (48-308) +final
______
Advanced topics in Ecology. Population modeling, global carbon cycle, climate change, geoengineering, theories of resource competition and mutualism, allometric scaling, ecological genomics, niche theory, human population growth. Applied ecology. Combination of 1.018A and 1.018B counts as REST subject.
O. Cordero, M. Follows
No required or recommended textbooks

1.020 Principles of Energy and Water Sustainability
______

Undergrad (Spring)
Prereq: Physics I (GIR);Coreq: 18.03 or permission of instructor
Units: 3-2-7
______
Introduces a systems approach to modeling, analysis, and decision-making problems for water and energy sustainability; formulation of models based on physical, environmental, social, and economic principles; and economic evaluation of design. Covers applications of mass balance, energy balance, and economic and lifecycle concepts. Uses numerical models to integrate concepts and to assess environmental impacts of human activities.
S. Amin

1.021 Introduction to Modeling and Simulation
______

Undergrad (Spring) Rest Elec in Sci & Tech
Engineering School-Wide Elective Subject.
(Offered under:1.021,3.021,10.333,22.00)
Prereq: 18.03, 3.016, or permission of instructor
Units: 4-0-8
______
Basic concepts of computer modeling and simulation in science and engineering. Uses techniques and software for simulation, data analysis and visualization. Continuum, mesoscale, atomistic and quantum methods used to study fundamental and applied problems in physics, chemistry, materials science, mechanics, engineering, and biology. Examples drawn from the disciplines above are used to understand or characterize complex structures and materials, and complement experimental observations.
M. Buehler, R. Taylor

1.022 Urban Networks
______

Undergrad (Fall); second half of term
Prereq: 1.00 or 1.000; 1.010
Units: 3-0-3
Begins Oct 31. Lecture: TR1-2.30 (1-150) Recitation: F1 (1-150)
______
Introduces the structure and evolution of networks with examples from engineering, applied mathematics, computer science, and statistical physics. Includes analysis of real world datasets focused on identifying important nodes in networks, detecting communities, tracing network flows, and modeling and visualization of spatial networks.
M. Gonzalez
No required or recommended textbooks

1.032 Advanced Soil Mechanics
______

Undergrad (Fall); first half of term
(Subject meets with1.361)
Prereq: 1.010, 1.011, 1.036
Units: 3-0-6
Ends Oct 21. Lecture: TR10.30-12 (1-246) Recitation: W4 (1-273) +final
______
Covers topics in the characterization and nature of soils as multi-phase materials; the principle of effective stress; hydraulic conductivity and groundwater seepage; shear strength and stability analyses; stress-deformation properties, consolidation theory and calculation of settlements for clays and sands. Students taking graduate version complete additional assignments.
A. Whittle
No required or recommended textbooks

1.035 Multiscale Characterization of Materials
______

Undergrad (Spring)
Prereq: 1.050, 18.03
Units: 3-3-6
______
Introduces the structure and properties of natural and manufactured building materials. Emphasizes effects of molecular and nanoscopic structure and interactions on macroscopic material behavior. Focuses on design of biological and artificial structural materials. Discusses material aspects of sustainable development. Includes durability, deterioration mechanisms, and damage assessment of building materials. Presents principles of experimental characterization techniques. Explores spectroscopic, microscopic and mechanical approaches to characterize structure and properties from molecular up to the macroscopic scale. In laboratory and in-field sessions, students design and implement experimental approaches to characterize natural and building materials and study their interaction with the environment.
F. Ulm

1.036 Structural Mechanics and Design
______

Undergrad (Spring)
Prereq: 1.035, 1.050
Units: 3-1-8
______
Familiarizes students with structural systems, loads, and basis for structural design, including analysis of determinate and indeterminate structures (trusses, beams, frames, cables, and arches). Covers mechanical properties of construction materials, including concrete, steel, and composites. Studies concrete and steel structures through application of principles of structural mechanics. Evaluates behavior and design of reinforced concrete structural elements using limit strength design and serviceability principles. Introduces plastic analysis and design, and load factor design of structural steel members and connections. Team project emphasizes material covered through behavior and problem-based learning.
O. Buyukozturk

1.037 Soil Mechanics and Geotechnical Design
______

Undergrad (Spring)
Prereq: None
Units: 3-2-7
______
Provides an introduction to soils as engineering materials, including classification and characterization, pore pressures and seepage, principles of effective stress and consolidation, deformation, and shear strength properties. Surveys analysis methods, with a focus on slope stability, limiting earth pressures and bearing capacity, and settlements of foundations. Examines applications in the design of earth dams, earth retaining systems, foundations, and staged construction processes.
A. Whittle

1.041 Transportation Systems Modeling
______

Undergrad (Spring)
Prereq: 1.00 or 1.000; 1.010
Units: 3-1-8
______
Introduces basic concepts of transportation systems modeling, data analysis and visualization techniques. Covers fundamental analytical and simulation-based methodologies. Topics include time-space diagrams, cumulative plots, queueing theory, network science, data analysis, and their applications. Provides students with an understanding of the current challenges and opportunities in different areas of transportation.
C. Osorio

1.044[J] Fundamentals of Energy in Buildings
______

Not offered academic year 2016-2017Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject as2.66[J],4.42[J])
Prereq: Physics I (GIR), Calculus II (GIR)
Units: 3-2-7
______
Design-based introduction to energy and thermo-sciences, with applications to sustainable, energy-efficient architecture and building technology. Covers introductory thermodynamics, air/water/vapor mixtures, and heat transfer. Studies leading order factors in building energy use. Includes several building design projects in which students creatively employ energy fundamentals and building energy use.
L. R. Glicksman

1.050 Solid Mechanics
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Physics I (GIR);Coreq: Calculus II (GIR)
Units: 3-2-7
Lecture: MWF11 (4-231) Lab: R3-5 (5-217) +final
______
Basic principles of mechanics to describe the behavior of materials, structures and fluids. Dimensional analysis, conservation of momentum, static equilibrium, stress and stress states, hydrostatics, moments and forces. Material and structural strength criteria. Deformation and strain. Conservation of energy in solid mechanics, elasticity and elasticity bounds. Energy dissipation, plasticity and fracture. Open-ended geotechnical and structural engineering studio exercises and experiments with natural and man-made physical systems.
F. J. Ulm
No required or recommended textbooks

1.053[J] Dynamics and Control I
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
(Same subject as2.003[J])
Prereq: Physics II;Coreq: 18.03 or 2.087
Units: 4-1-7
Lecture: TR9.30-11 (10-250) Recitation: R12 (5-233) or R1 (5-233) or R3 (5-233) or R4 (5-233) or F2 (1-246) or F3 (1-246) +final
______
Introduction to the dynamics and vibrations of lumped-parameter models of mechanical systems. Kinematics. Force-momentum formulation for systems of particles and rigid bodies in planar motion. Work-energy concepts. Virtual displacements and virtual work. Lagrange's equations for systems of particles and rigid bodies in planar motion. Linearization of equations of motion. Linear stability analysis of mechanical systems. Free and forced vibration of linear multi-degree of freedom models of mechanical systems; matrix eigenvalue problems.
J. K. Vandiver, N. C. Makris, N. M. Patrikalakis, T. Peacock, D. Gossard, K. Turitsyn
No required or recommended textbooks

1.054 Mechanics and Design of Concrete Structures
______

Undergrad (Fall)
(Subject meets with1.541)
Prereq: 1.035
Units: 3-0-9
Lecture: MW1-2.30 (1-246)
______
Studies strength and deformation of concrete under various states of stress; failure criteria; concrete plasticity; and fracture mechanics concepts. Topics include fundamental behavior of reinforced concrete structural systems and their members; basis for design and code constraints; high-performance concrete materials and their use in innovative design solutions; and yield line theory for slabs. Uses behavior models and nonlinear analysis. Covers complex systems, including bridge structures, concrete shells, and containments. Students taking graduate version complete additional assignments.
O. Buyukozturk
Textbooks (Fall 2016)

1.056[J] Building Structural Systems I
______

Undergrad (Spring) Rest Elec in Sci & Tech
(Same subject as4.440[J])
(Subject meets with4.462)
Prereq: Calculus II (GIR)
Units: 3-3-6
______
Introduces the design and behavior of large-scale structures and structural materials. Emphasizes the development of structural form and the principles of structural design. Presents design methods for timber, masonry, concrete and steel applied to long-span roof systems, bridges, and high-rise buildings. Includes environmental assessment of structural systems and materials. In laboratory sessions, students solve structural problems by building and testing simple models. Graduate and undergraduate students have separate lab sections.
J. Ochsendorf

1.058 Structural Dynamics & Vibrations
______

Undergrad (Fall)
(Subject meets with1.581[J],2.060[J],16.221[J])
Prereq: Permission of instructor
Units: 3-1-8
Lecture: MWF10 (1-390) Recitation: W4 (1-246)
______
Single- and multiple-degree-of-freedom vibration problems, using matrix formulation and normal mode superposition methods. Time and frequency domain solution techniques including convolution and Fourier transforms. Applications to vibration isolation, damping treatment, and dynamic absorbers. Analysis of continuous systems by exact and approximate methods. Applications to buildings, ships, aircraft and offshore structures. Vibration measurement and analysis techniques. Students should possess basic knowledge in structural mechanics and in linear algebra. Students taking graduate version complete additional assignments.
E. Kausel
No textbook information available

1.060A Fluid Mechanics I
______

Undergrad (Fall); first half of term
Prereq: Permission of instructor orCoreq: 18.03
Units: 2-1-3
Ends Oct 21. Lecture: MWF11 Lab: T10-12 or F2.30-4.30
______
Mechanics principles for incompressible fluids. Review of hydrostatics. Conservation of mass, momentum and energy in fluid mechanics. Flow nets, velocity distributions in laminar and turbulent flows, groundwater flows. Momentum and energy principles in hydraulics, with emphasis on open channel flow and hydraulic structures.
B. Marelli
Textbooks (Fall 2016)

1.060B Fluid Mechanics II
______

Undergrad (Fall); second half of term
Prereq: 1.060A
Units: 2-1-3
Begins Oct 24. Lecture: MWF11 Lab: T10-12 or F2.30-4.30 +final
______
Mechanics principles for incompressible fluids. Drag and lift forces. Analysis of pipe systems, pumps and turbines. Gradually varied flow in open channels, significance of the Froude number, backwater curves. Application of principles through open-ended studio exercises.
B. Marelli
Textbooks (Fall 2016)

1.061 Transport Processes in the Environment
______

Undergrad (Fall)
(Subject meets with1.61)
Prereq: 1.060B
Units: 3-1-8
Lecture: MWF10 (48-316) Recitation: F11 (48-316) +final
______
Introduction to mass transport in environmental flows, with emphasis on river and lake systems. Covers derivation and solutions to the differential form of mass conservation equations, hydraulic models for environmental systems, residence time distribution, molecular and turbulent diffusion for continuous and point sources, boundary layers, dissolution, bed-water exchange, air-water exchange, and particle transport. Meets with 1.061A first half of term. Students taking graduate version complete additional assignments.
H. M. Nepf
No required or recommended textbooks

1.061A Transport Processes in the Environment I
______

Undergrad (Fall); first half of term
Prereq: 1.060A
Units: 2-1-3
Ends Oct 21. Lecture: MWF10 (48-316) Recitation: F11 (48-316)
______
Introduction to mass transport in environmental flows. Covers derivation and solution to the differential form of mass conservation, hydraulic models for environmental systems, residence time distribution, and molecular and turbulent diffusion for continuous and point sources. Meets with 1.061 first half of term.
H. Nepf
No required or recommended textbooks

1.062[J] Nonlinear Dynamics: Continuum Systems
______

Undergrad (Spring)
(Same subject as12.207[J],18.354[J])
(Subject meets with18.3541)
Prereq: 18.03 or 18.034; Physics II (GIR)
Units: 3-0-9
______
General mathematical principles of continuum systems. From microscopic to macroscopic descriptions in the form of linear or nonlinear (partial) differential equations. Exact solutions, dimensional analysis, calculus of variations and singular perturbation methods. Stability, waves and pattern formation in continuum systems. Subject matter illustrated using natural fluid and solid systems found, for example, in geophysics and biology.
P. Pearce

1.064 Physical Limnology
______

Undergrad (Spring)
Not offered regularly; consult department
(Subject meets with1.64)
Prereq: 1.061
Units: 3-0-9
______
Provides an introduction to physical processes occurring in lakes and shallow surface water systems with emphasis on mechanisms affecting fate and transport. Topics include internal waves, differential heating and cooling, boundary mixing, turbulent mixing, and influence of vegetation. Begins with a review of Navier-Stokes equation. Students taking graduate version complete additional assignments.
H. M. Nepf

1.068 Nonlinear Dynamics and Turbulence
______

Not offered academic year 2017-2018Undergrad (Spring)
(Subject meets with1.686[J],18.358[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Reviews theoretical notions of nonlinear dynamics, instabilities, and waves with applications in fluid dynamics. Discusses hydrodynamic instabilities leading to flow destabilization and transition to turbulence. Focuses on physical turbulence and mixing from homogenous isotropic turbulence. Also covers topics such as rotating and stratified flows as they arise in the environment, wave-turbulence, and point source turbulent flows. Students taking graduate version complete additional assignments.
L. Bourouiba

1.070A[J] Introduction to Hydrology and Water Resources
______

Undergrad (Fall); first half of term
(Same subject as12.320A[J])
Prereq: 1.060A;Coreq: 1.061A, 1.106
Units: 2-0-4
Ends Oct 21. Lecture: TR9.30-11 (48-316) Recitation: M1 (48-308)
______
Water in the environment; Water resource systems; The hydrologic cycle at its role in the climate system; Surface water and energy balance; evaporation and transpiration through vegetation; Precipitation formation, infiltration, storm runoff, and flood processes; Groundwater aquifers, subsurface flow and the hydraulics of wells.
D. Entekhabi
No textbook information available

1.070B[J] Introduction to Hydrology Modeling
______

Undergrad (Fall); second half of term
(Same subject as12.320B[J])
Prereq: 1.070A
Units: 2-0-4
Begins Oct 24. Lecture: TR9.30-11 (48-316) Recitation: M1 (48-308)
______
Develops understanding of numerical modeling of aquifers, groundwater flow and contaminant transport, as well as uncertainty and risk analysis for water resources.
D. Entekhabi
No textbook information available

1.071[J] Global Change Science
______

Not offered academic year 2016-2017Undergrad (Fall)
(Same subject as12.300[J])
Prereq: 18.03
Units: 3-0-9
______
Introduces the basic relevant principles and concepts in atmospheric physics, climate dynamics, biogeochemistry, and water and energy balance at the land-atmosphere boundary, through an examination of two current problems in the global environment: carbon dioxide and global warming; and tropical deforestation and regional climate. An introduction to global environmental problems for students in basic sciences and engineering.
E. A. B. Eltahir

1.072 Groundwater Hydrology
______

Undergrad (Fall)
(Subject meets with1.72)
Prereq: 1.061
Units: 3-1-8
Lecture: MW2.30-4 (48-308) Recitation: TBA +final
______
Presents the fundamentals of subsurface flow and transport, emphasizing the role of groundwater in the hydrologic cycle, the relation of groundwater flow to geologic structure, and the management of contaminated groundwater. Topics include Darcy equation, flow nets, mass conservation, the aquifer flow equation, heterogeneity and anisotropy, storage properties, regional circulation, unsaturated flow, recharge, stream-aquifer interaction, well hydraulics, flow through fractured rock, numerical models, groundwater quality, contaminant transport processes, dispersion, decay, and adsorption. Includes laboratory and computer demonstrations. Students taking graduate version complete additional assignments.
C. Harvey
No textbook information available

1.073 Introduction to Environmental Data Analysis
______

Not offered academic year 2016-2017Undergrad (Spring); first half of term
Prereq: 1.010
Units: 2-0-4
______
Covers theory and practical methods for the analysis of univariate data sets. Topics include basics of statistical inference, analysis of trends and stationarity; Gaussian stochastic processes, covariance and correlation analysis, and introduction to spectral analysis. Students analyze data collected from the civil, environment, and systems domains.
E. Eltahir

1.074 Multivariate Data Analysis
______

Undergrad (Spring); second half of term
Prereq: 1.010
Units: 2-0-4
______
Introduction to statistical multivariate analysis methods and their applications to analyze data and mathematical models. Topics include sampling, experimental design, regression analysis, specification testing, dimension reduction, categorical data analysis, classification and clustering.
Staff

1.075 Water Resource Systems
(New)
______

Undergrad (Fall)
(Subject meets with1.731)
Prereq: 1.070B or permission of instructor
Units: 3-0-9
Lecture: TR2.30-4 (48-316) +final
______
Surveys optimization and simulation methods for management of water resources. Case studies illustrate linear, quadratic, nonlinear programming and real-time control. Applications include river basin planning, irrigation and agriculture, reservoir operations, capacity expansion, assimilation of remote sensing data, and sustainable resource development. Students taking graduate version complete additional assignments.
D. McLaughlin
No textbook information available

1.078 Introduction to Soil Science
(New)
______

Undergrad (Fall)
(Subject meets with1.78)
Prereq: None
Units: 3-1-8
Lecture: TR1-2.30 (48-308) Recitation: R4 (48-109) +final
______
Presents the physical, chemical, biological and genetic properties of soils, their global distribution, and response to management. Emphasizes factors controlling soil development, plant productivity, and the fate, cycling and bioavailability of soil nutrients and pollutants. Introduces Earth's different soil types and their classification; links characteristics with contemporary and historic issues surrounding natural and managed soil systems. Topics include soil carbon cycling, water and fertilizer management, and challenges associated with soil salinity-sodicity, erosion, and pollution. Includes field trips to local sites to examine soil physical properties, classification, and function. Introductory biology and chemistry are recommended prerequisites. Students taking graduate version complete additional assignments.
B. Kocar
Textbooks (Fall 2016)

1.080A Environmental Chemistry I
______

Undergrad (Spring); first half of term
Prereq: Chemistry (GIR)
Units: 2-0-4
______
Introduction to environmental chemistry with a focus on using thermodynamics to understand processes governing chemical behaviors in natural and engineered systems. Topics include vaporization, gas-solution partitioning, salt and mineral dissolution/precipitation, acid-base chemistry, metal complexation, adsorption via ion exchange, and absorption within natural organic matter and organism tissues. Process formulations are combined in box models to compare with observations.
P. M. Gschwend

1.080B Environmental Chemistry II
______

Undergrad (Spring); second half of term
Prereq: 1.080A
Units: 2-0-4
______
Intermediate topics in environmental chemistry requiring kinetics to understand processes governing biogeochemical behaviors in natural and engineered systems. Topics include radiochemistry, redox chemistry, surface chemistry and surface complexation. Introduction to geochemical modeling using reactive transport software; process formulations are combined in chemical fate models to compare with observations of concentrations as a function of space and time.
J. Kroll

1.081[J] Environmental Cancer Risks, Prevention, and Therapy
______

Undergrad (Spring)
(Same subject as20.104[J])
Prereq: Calculus II (GIR), Biology (GIR), Chemistry (GIR)
Units: 3-0-9
______
Analysis of the history of cancer and vascular disease mortality rates in predominantly European- and African-American US cohorts, 1895-2010, to discover specific historical shifts. Shifts identified are explored in terms of contemporaneously changing environmental risk factors: air-, food- and water-borne chemicals; subclinical infections; diet and lifestyles. Role of occupational data identifying general risk factors. Considers the hypotheses that environmental factors affect metakaryotic stem cell mutation rates in fetuses and juveniles and/or the growth rates of preneoplastic stem cells in adults. Interaction of environmental and inherited risks. Introduces the use of metakaryocidal drugs to treat cancer in clinical trials.
W. Thilly, R. McCunney

1.082 Ethics for Engineers
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.082,2.900,6.904,10.01,22.014)
Prereq: None
Units: 2-0-4
Lecture: M3-5 (66-144, 36-153) or T3-5 (37-212) or T EVE (7.30-9.30 PM) (66-144) or W3-5 (36-153)
______
Integrates classical readings that provide an overview of ethics with a survey of case studies that focus on ethical problems arising in the practice of engineering. Readings taken from a variety of sources, such as Aristotle, Machiavelli, Bacon, Hobbes, Locke, the Founding Fathers, and the Bible. Case studies include written analyses and films that address engineering disasters, biotechnology, court cases, ethical codes, and the ultimate scope and aims of engineering.
D. Doneson, B. L. Trout
No textbook information available

1.084[J] Systems Microbiology
______

Undergrad (Fall)
(Same subject as20.106[J])
Prereq: Chemistry (GIR), Biology (GIR)
Units: 3-0-9
Lecture: TR2.30-4 (56-614)
______
Introductory microbiology from a systems perspective - considers microbial diversity and the integration of data from a molecular, cellular, organismal, and ecological context to understand the interaction of microbial organisms with their environment. Special emphasis on specific viral, bacterial, and eukaryotic microorganisms and their interaction with animal hosts with focus on contemporary problems in areas such as vaccination, emerging disease, antimicrobial drug resistance, and toxicology.
E. Alm, J. Niles
No textbook information available

1.085[J] Air Pollution
______

Undergrad (Fall)
(Same subject as12.336[J])
Prereq: 18.03
Units: 3-0-9
Lecture: MW10.30-12 (48-308)
______
Provides a working knowledge of basic air quality issues, with emphasis on a multidisciplinary approach to investigating the sources and effects of pollution. Topics include emission sources; atmospheric chemistry and removal processes; meteorological phenomena and their impact on pollution transport at local to global scales; air pollution control technologies; health effects; and regulatory standards. Discusses regional and global issues, such as acid rain, ozone depletion and air quality connections to climate change.
C. Heald
Textbooks (Fall 2016)

1.089 Environmental Microbiology
______

Undergrad (Spring)
(Subject meets with1.89)
Prereq: Biology (GIR)
Units: 3-0-9
______
Provides a general introduction to the diverse roles of microorganisms in natural and artificial environments. Topics include energetics and growth, evolution and gene flow, population and community dynamics, water and soil microbiology, biogeochemical cycling, and microorganisms in biodeterioration and bioremediation. 7.014 recommended as prerequisite; students taking graduate version complete additional assignments. Meets with 1.089A first half of term.
M. Polz, O. Cordero

1.089A Environmental Microbiology I
(New)
______

Undergrad (Spring); first half of term
Prereq: Biology (GIR) or permission of instructor
Units: 3-0-3
______
Provides a general introduction to the diverse roles of microorganisms in natural and artificial environments. Topics include energetics, and growth; metabolic interactions; water and soil microbiology; biogeochemical cycling; microbial diversity. 7.014 recommended as prerequisite. Meets with 1.089 first half of term.
M. Polz, O. Cordero

1.091 Traveling Research Environmental eXperience (TREX): Fieldwork
______

Undergrad (IAP)
Prereq: Permission of instructor
Units: 1-2-0
______
Introduction to environmental fieldwork and research, with a focus on data collection and analysis. Subject spans three weeks, including two weeks of fieldwork, and involves one or more projects central to environmental science and engineering. Location varies year-to-year, though recent projects have focused on the island of Hawaii. Limited to Course 1 students.
B. Kocar

1.092 Traveling Research Environmental eXperience (TREX): Fieldwork Analysis and Communication
______

Undergrad (Spring)
Prereq: 1.091
Units: 1-3-5
______
Building on fieldwork and research conducted in 1.091 over IAP, students focus on interpretation of results and research in support of the fieldwork, with instruction and practice in oral and written communication. Includes a survey of the relevant peer-reviewed literature; laboratory measurements of field samples and/or instrumental response; data analysis and interpretation; and dissemination of results. Culminates in presentation of research project(s), and write-ups of the research in manuscript form. Sequence of 1.091 and 1.092 must be completed in consecutive terms. Limited to Course 1 majors and minors.
B. Kocar

1.095 Teaching Practicum in Civil and Environmental Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Students work as unpaid laboratory, tutorial, or classroom assistants under supervision of a faculty member. Limited to Undergraduate Teaching Fellows and graders in Course 1.
Staff
No textbook information available

1.097 Introduction to Civil and Environmental Engineering Research
______

Undergrad (IAP)
Prereq: None
Units: 1-5-0 [P/D/F]
______
Students work one-on-one with a CEE graduate student or postdoc mentor on a project that aligns with their research interests. Previous project topics include transportation networks, structural mechanics, sediment transport, climate science, and microbial ecology. Includes weekly seminar-style talks. Intended for first-year students.
Staff

Undergraduate Laboratory Subjects

1.101 Introduction to Civil and Environmental Engineering Design I
______

Undergrad (Fall) 1/2 Institute Lab
Prereq: None
Units: 0-4-2
Lab: TR1-3 (1-050)
______
Introduces the creative design process in the context of civil and environmental engineering. Emphasizes the idea-to-product trajectory: identification of a design question/problem, evaluation of requirements/constraints set by the application and/or client, and implementation into a concrete product deliverable. Fosters active learning through open-ended, student-driven projects in which teams apply the design process to a design/planning problem. In labs, students design and build a working model or an experiment that addresses a specific engineering aspect of their project. In addition to written and oral presentations, students start a web-based portfolio. Enrollment limited; preference to Course 1 majors and minors.
P. Reis
No required or recommended textbooks

1.102 Introduction to Civil and Environmental Engineering Design II
______

Undergrad (Spring) 1/2 Institute Lab
Prereq: Physics II (GIR); orCoreq: 1.060B and permission of instructor
Units: 1-3-2
______
Project-oriented subject focused on the principles and practice of engineering design. Emphasis on construction and deployment of designs, plus performance testing used to determine if designs behave as expected. Includes a major team project involving use and application of sensors, as well as environmentally-friendly, and energy-effective or energy-producing designs. Develops practical, teamwork and communication skills. Enrollment limited; preference to Course 1 majors and minors.
A. Masic

1.106 Environmental Fluid Transport Processes and Hydrology Laboratory
______

Undergrad (Fall) 1/2 Institute Lab
Prereq: None.Coreq: 1.061A, 1.070A
Units: 0-4-2
Lab: W1-5 (48-109)
______
Fundamentals of mass transport and flow measurements in the context of environmental systems. Topics include measurement uncertainty, propagation of error, diffusion, dispersion, air-water exchange, dissolution, gravity currents, particle transport, and transport in porous media. Includes formal lab reports. Enrollment limited; preference to 1-ENG.
H. Nepf, D. Entekhabi
No required or recommended textbooks

1.107 Environmental Chemistry and Biology Laboratory
______

Undergrad (Spring) 1/2 Institute Lab
Prereq: 1.018A or permission of instructor;Coreq: 1.080A
Units: 0-4-2
______
Laboratory and field techniques in biogeochemistry and environmental engineering and their application to the understanding of natural and engineered ecosystems. Exercises demonstrate data acquisition and modeling suited to identifying and quantifying physical, chemical, and biological processes that govern the effects of human activity on the functioning of natural systems and/or the efficacy of engineered approaches to environmental problems. Applications include chemical and biological remediation, measurement of contaminants, and detection of biogeochemical activity in natural environments. An independently designed final project is required. Enrollment limited; preference to 1-ENG.
P. Gschwend, B. Kocar

Engineering Information Systems and Computation

1.124[J] Software and Computation for Simulation
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as2.091[J])
Prereq: 1.00 or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/1.124/www/
______
Modern software development techniques and algorithms for engineering computation. Hands-on investigation of computational and software techniques for simulating engineering systems, such as sensor networks, traffic networks, and discrete simulation of materials using atomistic and particle methods. Covers data structures and algorithms for modeling, analysis, and visualization in the setting of multi-core and distributed computing. Treatment of basic topics, such as queuing, sorting and search algorithms, and more advanced numerical techniques based on state machines and distributed agents. Foundation for in-depth exploration of image processing, optimization, finite element and particle methods, computational materials, discrete element methods, and network methods. Knowledge of an object-oriented language required.
J. R. Williams

1.125 Architecting & Engineering Software Systems
______

Graduate (Fall)
Prereq: 1.00, 1.124J, or permission of instructor
Units: 3-0-9
Lecture: TR12.30-2 (48-316)
______
Software architecting and design of software-intensive systems. Targeted at future CTOs who must understand both the business and technical issues involved in architecting enterprise-scale systems. Student teams confront technically challenging problems. Lectures and readings cover core database, XML, web server components and browser issues in a distributed web service environment. Enrollment limited.
J. Williams
No required or recommended textbooks

1.126[J] Pattern Recognition and Analysis
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject asMAS.622[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Fundamentals of characterizing and recognizing patterns and features of interest in numerical data. Basic tools and theory for signal understanding problems with applications to user modeling, affect recognition, speech recognition and understanding, computer vision, physiological analysis, and more. Decision theory, statistical classification, maximum likelihood and Bayesian estimation, nonparametric methods, unsupervised learning and clustering. Additional topics on machine and human learning from active research. Knowledge of probability theory and linear algebra required. Limited to 20.
R. W. Picard

1.128[J] Computational Geometry
______

Graduate (Spring)
Not offered regularly; consult department
(Same subject as 2.089[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Topics in surface modeling: b-splines, non-uniform rational b-splines, physically based deformable surfaces, sweeps and generalized cylinders, offsets, blending and filleting surfaces. Non-linear solvers and intersection problems. Solid modeling: constructive solid geometry, boundary representation, non-manifold and mixed-dimension boundary representation models, octrees. Robustness of geometric computations. Interval methods. Finite and boundary element discretization methods for continuum mechanics problems. Scientific visualization. Variational geometry. Tolerances. Inspection methods. Feature representation and recognition. Shape interrogation for design, analysis, and manufacturing. Involves analytical and programming assignments.
N. M. Patrikalakis, D. C. Gossard

Engineering Analysis Methods

1.138[J] Wave Propagation
______

Graduate (Spring)
(Same subject as2.062[J],18.376[J])
Prereq: 2.003, 18.075
Units: 3-0-9
URL: http://math.mit.edu/classes/18.376/
______
Theoretical concepts and analysis of wave problems in science and engineering with examples chosen from elasticity, acoustics, geophysics, hydrodynamics, blood flow, nondestructive evaluation, and other applications. Progressive waves, group velocity and dispersion, energy density and transport. Reflection, refraction and transmission of plane waves by an interface. Mode conversion in elastic waves. Rayleigh waves. Waves due to a moving load. Scattering by a two-dimensional obstacle. Reciprocity theorems. Parabolic approximation. Waves on the sea surface. Capillary-gravity waves. Wave resistance. Radiation of surface waves. Internal waves in stratified fluids. Waves in rotating media. Waves in random media.
T. R. Akylas, R. R. Rosales

See also 1.351, 1.541, 1.56J, 1.63, 1.691.

Engineering Systems, Economics, and Optimization

1.142[J] Robust Modeling, Optimization, and Computation
______

Graduate (Spring)
(Same subject as15.094[J])
Prereq: 18.06 or permission of instructor
Units: 4-0-8
______
Introduces modern robust optimization, including theory, applications, and computation. Presents formulations and their connection to probability, information and risk theory for conic optimization (linear, second-order, and semidefinite cones) and integer optimization. Application domains include analysis and optimization of stochastic networks, optimal mechanism design, network information theory, transportation, pattern classification, structural and engineering design, and financial engineering. Students formulate and solve a problem aligned with their interests in a final project.
D. Bertsimas

1.145[J] Engineering Economy Module
______

Graduate (Fall); partial term
(Same subject asIDS.331[J])
Prereq: None
Units: 1-0-2 [P/D/F]
Subject Cancelled Subject Cancelled
______
Presentation of the spreadsheet mechanics for the efficient calculation of discounted cash flows and related metrics of project worth; the use of data tables as means of exploring sensitivity analysis; and of simulation to develop the value of options. Intensive module designed for students who are not familiar with the efficient use of Excel. Presented intensively over first week of term.
R. de Neufville

1.146 Engineering Systems Analysis for Design
______

Graduate (Fall)
Engineering School-Wide Elective Subject.
(Offered under:1.146,16.861,IDS.332)
(Subject meets withIDS.333)
Prereq: 1.145 or permission of instructor
Units: 3-0-9
URL: http://msl1.mit.edu/mib/dsp/curricula.mit.edu/~dsplan/
Lecture: TR10.30-12 (1-390)
______
Covers theory and methods to identify, value, and implement flexibility in design, also known as "real options." Topics include definition of uncertainties, simulation of performance for scenarios, screening models to identify desirable flexibility, decision and lattice analysis, and multidimensional economic evaluation. Students demonstrate proficiency through an extended application to a systems design of their choice. Provides a complement to research or thesis projects. Meets with IDS.333 first half of term.
R. de Neufville
Textbooks (Fall 2016)

See also 1.202J, 1.203J, 1.283J, 1.731. For management of engineering systems, see also 1.040, 1.401J-1.482.


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Produced: 29-SEP-2016 06:37 AMFall 2016 Course 1: Civil and Environmental Engineering
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Course 1: Civil and Environmental Engineering
Fall 2016


Engineering Risk Assessment and Probabilistic Analysis

1.151 Probability and Statistics in Engineering
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces probability and statistics for engineering applications. Topics in probability include events and their probability, Total Probability and Bayes' Theorems, discrete and continuous random variables and vectors, Bernoulli Trial Sequence and Poisson point process, functions of random variables and vectors and conditional uncertainty analysis using full-distribution and second-moment uncertainty representation. Topics in statistics include estimation of distribution parameters, hypothesis testing, and simple linear regression. Concepts illustrated with examples from various areas of engineering and everyday life.
D. Veneziano

1.153 Transportation Policy, the Environment, and Livable Communities
______

Undergrad (Spring)
(Subject meets with1.253[J],11.543[J])
Prereq: 1.011
Units: 3-0-9
______
Examines the economic and political conflict between transportation and the environment. Investigates the role of government regulation, green business and transportation policy as a facilitator of economic development and environmental sustainability. Analyzes a variety of international policy problems, including government-business relations, the role of interest groups, non-governmental organizations, and the public and media in the regulation of the automobile; sustainable development; global warming; politics of risk and siting of transport facilities; environmental justice; equity; as well as transportation and public health in the urban metropolis. Provides students with an opportunity to apply transportation and planning methods to develop policy alternatives in the context of environmental politics. Students taking graduate version complete additional assignments.
J. Coughlin

See also 1.203J.

Transportation

1.200[J] Transportation Systems Analysis: Performance and Optimization
______

Graduate (Fall)
(Same subject as11.544[J])
Prereq: 1.010, permission of instructor
Units: 3-1-8
Lecture: TR10.30-12 (3-370) Recitation: R4 (3-370)
______
Problem-motivated introduction to methods, models and tools for the analysis and design of transportation networks including their planning, operations and control. Capacity of critical elements of transportation networks. Traffic flows and deterministic and probabilistic delay models. Formulation of optimization models for planning and scheduling of freight, transit and airline systems, and their solution using software packages. User- and system-optimal traffic assignment. Control of traffic flows on highways, urban grids, and airspace.
C. Osorio
No required or recommended textbooks

1.201[J] Transportation Systems Analysis: Demand and Economics
______

Graduate (Fall)
(Same subject as11.545[J])
Prereq: Permission of instructor
Units: 3-1-8
Lecture: TR2.30-4 (2-105) Recitation: F11 (2-105) +final
______
Covers the key principles governing transportation systems planning and management. Introduces the microeconomic concepts central to transportation systems. Topics include economic theories of the firm, consumer, and market, demand models, discrete choice analysis, cost models and production functions, and pricing theory. Applications to transportation systems - including congestion pricing, technological change, resource allocation, market structure and regulation, revenue forecasting, public and private transportation finance, and project evaluation - cover urban passenger transportation, freight, maritime, aviation, and intelligent transportation systems.
Staff
Textbooks (Fall 2016)

1.202 Demand Modeling
______

Graduate (Spring)
Prereq: 1.201 or permission of instructor
Units: 3-1-8
______
Theory and application of modeling and statistical methods for analysis and forecasting of demand for facilities, services, and products. Topics include: review of probability and statistics, estimation and testing of linear regression models, theory of individual choice behavior, derivation, estimation, and testing of discrete choice models (including logit, nested logit, GEV, probit, and mixture models), estimation under various sample designs and data collection methods (including revealed and stated preferences), sampling, aggregate forecasting methods, and iterative proportional fitting and related methods. Lectures reinforced with case studies, which require specification, estimation, testing, and analysis of models using data sets from actual applications.
Staff

1.203[J] Logistical and Transportation Planning Methods
______

Graduate (Spring)
(Same subject as15.073[J],16.76[J])
Prereq: 6.041B
Units: 3-0-9
______
Quantitative techniques of operations research with emphasis on applications in transportation systems analysis (urban, air, ocean, highway, and pickup and delivery systems) and in the planning and design of logistically oriented urban service systems (e.g., fire and police departments, emergency medical services, and emergency repair services). Unified study of functions of random variables, geometrical probability, multi-server queuing theory, spatial location theory, network analysis and graph theory, and relevant methods of simulation. Computer exercises and discussions of implementation difficulties.
R. C. Larson, A. I. Barnett

1.204 Computer Modeling: From Human Mobility to Transportation Networks
______

Graduate (Spring)
Prereq: 1.001, 1.010; or permission of instructor
Units: 3-0-9
______
Introduces methods for modeling individual travels at a country scale. Reviews basic concepts of data analysis, modeling, and visualization techniques. Topics include data mining to identify the structure inherent in daily behavior; introduction to fractals, random walks and methods to analyze trajectories. Algorithms to model and characterize complex networks, and their applications to daily commuting, air travels, and roads. Includes weekly open laptop exercises based on the data sets and methods from the research papers covered in class. Exposes students to the current challenges and opportunities in networks applied to human mobility.
M. C. Gonzalez

1.205 Advanced Demand Modeling
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 1.202 or permission of instructor
Units: 3-0-9
______
Advanced theories and applications of models for analysis and forecasting of users' behavior and demand for facilities, services, and products. Topics vary each year and typically include linear and nonlinear latent variable models, including structural equations and latent class models; estimation techniques with multiple data sources; joint discrete and continuous choice models; dynamic models; analysis of panel data; analysis of complex choices; estimation and forecasting with large choice sets; multidimensional probabilistic choice models; advanced choice models, including probit, logit mixtures, treatment of endogeneity, hybrid choice models, hidden Markov models, Monte Carlo simulation, Bayesian methods, survey design, sampling, model transferability, and use of stated preferences data. Term paper required.
M. E. Ben-Akiva

1.207 Computer Algorithms in Systems Engineering
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: 1.001 or permission of instructor
Units: 3-0-9
______
Covers concepts of computation in analysis of engineering systems. Data structures, relational database representations of engineering data. Algorithms for the solution and optimization of engineering system designs: greedy, dynamic programming, branch and bound, graph algorithms, nonlinear optimization. Provides an introduction to complexity analysis. Object-oriented, efficient implementations of algorithms.
Staff

1.208 Resilient Infrastructure Networks
______

Graduate (Fall)
Prereq: 1.151 or 6.431B; 15.093
Units: 3-0-9
Lecture: MW1-2.30 (5-233)
______
Control algorithms and game-theoretic tools to enable resilient operation of large-scale infrastructure networks. Dynamical network flow models, stability analysis, robust predictive control, fault and attack diagnostic tools. Strategic network design, routing games, congestion pricing, demand response, and incentive regulation. Design of operations management strategies for different reliability and security scenarios. Applications to transportation, logistics, electric-power, and water distribution networks.
S. Amin
No required or recommended textbooks

1.231[J] Planning and Design of Airport Systems
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as16.781[J],IDS.670[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (1-379)
______
Focuses on current practice, developing trends, and advanced concepts in airport design and planning. Considers economic, environmental, and other trade-offs related to airport location, as well as the impacts of emphasizing "green" measures. Includes an analysis of the effect of airline operations on airports. Topics include demand prediction, determination of airfield capacity, and estimation of levels of congestion; terminal design; the role of airports in the aviation and transportation system; access problems; optimal configuration of air transport networks and implications for airport development; and economics, financing, and institutional aspects. Special attention to international practice and developments.
R. de Neufville, A. R. Odoni
Textbooks (Fall 2016)

1.232[J] The Airline Industry
______

Graduate (Fall)
(Same subject as15.054[J],16.71[J])
Prereq: None
Units: 3-0-9
Lecture: MW1-2.30 (35-225)
______
Overview of the global airline industry, focusing on recent industry performance, current issues and challenges for the future. Fundamentals of airline industry structure, airline economics, operations planning, safety, labor relations, airports and air traffic control, marketing, and competitive strategies, with an emphasis on the interrelationships among major industry stakeholders. Recent research findings of the MIT Global Airline Industry Program are showcased, including the impacts of congestion and delays, evolution of information technologies, changing human resource management practices, and competitive effects of new entrant airlines. Taught by faculty participants of the Global Airline Industry Program.
P. P. Belobaba, A. I. Barnett, C. Barnhart, R. J. Hansman, T. A. Kochan
Textbooks (Fall 2016)

1.233[J] Air Transportation Operations Research
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as16.763[J])
Prereq: 16.71, 6.431, 15.093, or permission of instructor
Units: 3-0-9
______
Presents a unified view of advanced quantitative analysis and optimization techniques applied to the air transportation sector. Considers the problem of operating and managing the aviation sector from the perspectives of the system operators (e.g., the FAA), the airlines, and the resultant impacts on the end-users (the passengers). Explores models and optimization approaches to system-level problems, airline schedule planning problems, and airline management challenges. Term paper required.
H. Balakrishnan, C. Barnhart, P. P. Belobaba

1.234[J] Airline Management
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as16.75[J])
Prereq: 16.71J
Units: 3-0-9
______
Overview of airline management decision processes, with a focus on economic issues and their relationship to operations planning models and decision support tools. Application of economic models of demand, pricing, costs, and supply to airline markets and networks. Examination of industry practice and emerging methods for fleet planning, route network design, scheduling, pricing and revenue management, with emphasis on the interactions between the components of airline management and profit objectives in competitive environments. Students participate in a competitive airline management simulation game as part of the subject requirements.
P. P. Belobaba

1.251[J] Comparative Land Use and Transportation Planning
______

Graduate (Spring)
(Same subject as11.526[J])
Prereq: Permission of Instructor
Units: 3-0-9
______
Focuses on the integration of land use and transportation planning, drawing from cases in both industrialized and developing countries. Reviews underlying theories, analytical techniques, and the empirical evidence of the land use-transportation relationship at the metropolitan, intra-metropolitan, and micro-scales. Also covers the various ways of measuring urban structure, form, and the "built environment." Develops students' skills to assess relevant policies, interventions and impacts.
C. Zegras

1.252[J] Urban Transportation Planning
______

Graduate (Fall)
(Same subject as11.540[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: F2-5 (5-217)
______
Studies the history, policy, practice and politics of urban transportation. Covers the role of the federal, state, and local government and the MPO, public transit in the auto era, analysis of current trends and pattern breaks; analytical tools for transportation planning, traffic engineering and policy analysis; the contribution of transportation to air pollution, social costs and climate change; land use and transportation interactions; traffic and place making; bicycles, pedestrians, and traffic calming. Examples from the Boston area and from Bilbao.
F. Salvucci, M. Murga
No textbook information available

1.253[J] Transportation Policy, the Environment, and Livable Communities
______

Graduate (Spring)
(Same subject as11.543[J])
(Subject meets with1.153)
Prereq: Permission of instructor
Units: 3-0-9
______
Examines the economic and political conflict between transportation and the environment. Investigates the role of government regulation, green business and transportation policy as a facilitator of economic development and environmental sustainability. Analyzes a variety of international policy problems, including government-business relations, the role of interest groups, non-governmental organizations, and the public and media in the regulation of the automobile; sustainable development; global warming; politics of risk and siting of transport facilities; environmental justice; equity; as well as transportation and public health in the urban metropolis. Provides students with an opportunity to apply transportation and planning methods to develop policy alternatives in the context of environmental politics. Students taking graduate version complete additional assignments.
J. Coughlin

1.254 Transport Modeling Course
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Fosters practical experience with the concepts and approaches behind the analytical chain composed by GIS, 4-step planning, and traffic models. Study conducted in Greater Boston. Students develop road and street, pedestrian, and public transportation networks. Uses the latest Census Transportation Planning Products (CTPP) data, and Boston home travel survey to understand travel behavior and calibrate model. Final project involves the design of alternative futures for the metropolitan area with different transportation and land use policies.
Staff

1.258[J] Public Transportation Systems
______

Graduate (Spring)
(Same subject as11.541[J])
Prereq: 1.201 or permission of instructor
Units: 3-0-9
______
Discusses evolution and role of urban public transportation modes, systems and services, focusing on bus and rail. Describes technological characteristics and their impacts on capacity, service quality, and cost. Current practice and new methods for data collection and analysis, performance monitoring, route and network design, frequency determination, and vehicle and crew scheduling. Effect of pricing policy and service quality on ridership. Methods for estimating costs associated with proposed service changes. Organizational models for delivering public transportation service including finance and operations.
Staff

1.260[J] Logistics Systems
______

Graduate (Fall)
(Same subject as15.770[J],IDS.730[J],SCM.260[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: MW8.30-10 (E51-315)
______
Provides an introduction to supply chain management from both analytical and practical perspectives. Taking a unified approach, students develop a framework for making intelligent decisions within the supply chain. Covers key logistics functions, such as demand planning, procurement, inventory theory and control, transportation planning and execution, reverse logistics, and flexible contracting. Explores concepts such as postponement, portfolio management, and dual sourcing. Emphasizes skills necessary to recognize and manage risk, analyze various tradeoffs, and model logistics systems.
Y. Sheffi, C. Caplice
Textbooks (Fall 2016)

1.261[J] Case Studies in Logistics and Supply Chain Management
______

Graduate (Spring)
(Same subject as15.771[J],SCM.261[J])
Prereq: Permission of instructor
Units: 3-0-6
______
A combination of lectures and cases covering the strategic, management, and operating issues in contemporary logistics and integrated supply chain management. Includes: logistics strategy; supply chain restructuring and change management; and distribution, customer service, and inventory policy.
J. Byrnes

1.265[J] Global Supply Chain Management
______

Graduate (Spring)
(Same subject as2.965[J],15.765[J],SCM.265[J])
Prereq: 1.260, 1.261, 15.761, 15.778, or permission of instructor
Units: 2-0-4
______
Focuses on the planning, processes, and activities of supply chain management for companies involved in international commerce. Students examine the end-to-end processes and operational challenges in managing global supply chains, such as the basics of global trade, international transportation, duty, taxes, trade finance and hedging, currency issues, outsourcing, cultural differences, risks and security, and green supply chains issues. Highly interactive format features student-led discussions, staged debates, and a mock trial. Includes assignments on case studies and sourcing analysis, as well as projects and a final exam.
B. Arntzen

1.27 Studies in Transportation
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Individual advanced study of a topic in transportation systems, selected with the approval of the instructor.
Staff
No textbook information available

1.271[J] The Theory of Operations Management
______

Graduate (Spring) Can be repeated for credit
(Same subject as15.764[J],IDS.155[J])
Prereq: 15.081J or 6.251J, 6.436J; or permission of instructor
Units: 3-0-9
______
Provides mathematical foundations underlying the theory of operations management. Covers application domains, including inventory management, supply chain management and logistics, behavioral operations, healthcare management, service industries, pricing and revenue management, and auctions. Studies a wide range of mathematical and analytical techniques, such as dynamic programming, stochastic orders, behavioral and experimental economics, algorithms and approximations, data-driven and learning models, and mechanism design. Also provides hands-on experience in how to apply the theoretical models to solve OM problems in concrete business settings. Specific topics vary from year to year.
I. Ashlagi, D. Simchi-Levi, K. Zheng

1.273[J] Supply Chain Planning
______

Graduate (Spring)
(Same subject as15.762[J],IDS.150[J])
Prereq: 1.260 or 15.761
Units: 2-0-4
______
Focuses on effective supply chain strategies for companies that operate globally, with emphasis on how to plan and integrate supply chain components into a coordinated system. Students are exposed to concepts and models important in supply chain planning with emphasis on key tradeoffs and phenomena. Introduces and utilizes key tactics such as risk pooling and inventory placement, integrated planning and collaboration, and information sharing. Lectures, computer exercises, and case discussions introduce various models and methods for supply chain analysis and optimization. Recommended for Operations Management concentrators. First half-term subject.
Staff

1.274[J] Manufacturing System and Supply Chain Design
______

Graduate (Spring)
(Same subject as15.763[J],IDS.151[J])
Prereq: 1.260, 15.761, or 15.778
Units: 2-0-4
______
Focuses on decision making for system design, as it arises in manufacturing systems and supply chains. Students exposed to frameworks and models for structuring the key issues and trade-offs. Presents and discusses new opportunities, issues and concepts introduced by the internet and e-commerce. Introduces various models, methods and software tools for logistics network design, capacity planning and flexibility, make-buy, and integration with product development. Industry applications and cases illustrate concepts and challenges. Recommended for Operations Management concentrators. Second half-term subject.
S. C. Graves, D. Simchi-Levi

1.275[J] Business and Operations Analytics
______

Not offered academic year 2016-2017Graduate (Spring); first half of term
(Same subject asIDS.305[J])
Prereq: 1.145 or permission of instructor
Units: 2-0-4
______
Provides instruction on identifying, evaluating, and capturing business analytics opportunities that create value. Also provides basic instruction in analytics methods and case study analysis of organizations that successfully deployed these techniques.
D. Simchi-Levi

1.284[J] Analyzing and Accounting for Regional Economic Change
______

Graduate (Spring)
(Same subject as11.481[J])
Prereq: 14.03, 14.04
Units: 3-0-9
______
Surveys theories of regional growth, factor mobility, clustering, industrial restructuring, learning regions, and global supply chains from a political-economy perspective. Examines/critiques multipliers, linkages, and supply chains used to assess employment and environmental impacts, energy and infrastructure investments, and accounting issues related to the underground economy, work in the home, and environmental degradation. Assesses price indices, industrial location and employment measures, and shift-share analyses. Discussions of US and foreign applications.
Staff

1.285[J] Regional Socioeconomic Impact Analyses and Modeling
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as11.482[J])
Prereq: 11.481J or permission of instructor
Units: 2-1-9
URL: http://web.mit.edu/11.482/www/Syllabus482-2001.html
______
Reviews regional economic theories and models and provides students with experience in using alternative economic impact assessment models on microcomputers. Problem sets are oriented around infrastructure, housing, energy, and environmental issues. Students work with a client generally in Boston and make a presentation to the client. Emphasis on written and oral presentation skills.
K. R. Polenske

1.286[J] Urban Energy Systems and Policy
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as11.477[J])
(Subject meets with11.165)
Prereq: 11.203, 14.01, or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Examines efforts in developing and advanced nations and regions. Examines key issues in the current and future development of urban energy systems, such as technology, use, behavior, regulation, climate change, and lack of access or energy poverty. Case studies on a diverse sampling of cities explore how prospective technologies and policies can be implemented. Includes intensive group research projects, discussion, and debate.
D. Hsu

Geoenvironmental and Geotechnical Engineering

1.322 Soil Behavior
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 1.361
Units: 4-0-8
______
Detailed study of soil properties with emphasis on interpretation of field and laboratory test data and their use in soft-ground construction engineering. Includes: consolidation and secondary compression; basic strength principles; stress-strain strength behavior of clays, emphasizing effects of sample disturbance, anisotropy, and strain rate; strength and compression of granular soils; and engineering properties of compacted soils. Some knowledge of field and laboratory testing assumed; 1.37 desirable.
A. J. Whittle

1.331 Advanced Soil Dynamics
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: Permission of Instructor
Units: 3-0-9
______
Review of linear vibration theory for single- and multiple degree-of-freedom systems and for continuous systems. Propagation of waves in soils; soil amplification in vertically inhomogeneous media, including iterative method for inelastic media. Dynamic stiffness of foundations, vibration of machine foundations, effective motion of foundations for earthquake waves, inertial soil-structure interaction. Absorbing boundaries. Inelastic behavior of soils, non-linear response of soils under dynamic loads. Sliding block analysis, dynamic slope stability, liquefaction.
E. Kausel

1.351 Theoretical Soil Mechanics
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 1.361
Units: 3-0-9
______
Presentation of fundamental theories in soil mechanics: field equations of linear elasticity and solutions of boundary value problems. Introduction to finite element method. Steady and transient flow in porous media; applications in confined and unconfined seepage, and one-dimensional consolidation. Introduction to poro-elasticity. Yielding and failure of soils; plasticity theory and limit analyses, with examples for bearing capacity and slope stability. Cam Clay models and critical state theory of soil behavior.
A. J. Whittle

1.361 Advanced Soil Mechanics
______

Graduate (Fall); first half of term
(Subject meets with1.032)
Prereq: 1.036
Units: 3-0-6
Ends Oct 21. Lecture: TR10.30-12 (1-246) Recitation: W8.30 (1-371) +final
______
Covers topics in the characterization and nature of soils as multi-phase materials; the principle of effective stress; hydraulic conductivity and groundwater seepage; shear strength and stability analyses; stress-deformation properties, consolidatoin theory and calculation of settlements for clays and sands.
A. Whittle
No required or recommended textbooks

1.364 Advanced Geotechnical Engineering
______

Graduate (Fall); second half of term
Prereq: 1.361
Units: 3-0-6
Begins Oct 24. Lecture: TR10.30-12 (1-246) Recitation: W8.30 (1-371)
______
Methodology for site characterization and geotechnical aspects of the design and construction of foundation systems. Topics include site investigation (with emphasis on in situ testing), shallow (footings and raftings) and deep (piles and caissons) foundations, excavation support systems, groundwater control, slope stability, soil improvement (compaction, soil reinforcement, etc.), and construction monitoring.
A. Whittle
No required or recommended textbooks

1.37 Geotechnical Measurements and Exploration
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 1.035
Units: 3-4-2
______
Application of testing principles to the measurement of fundamental aspects of soil behavior from classification to engineering properties. Emphasis on rigorous techniques to measure mechanical behavior under various boundary conditions. Exposure to error estimation, research devices, geotechnical field exploration, andin situ testing. Extensive laboratory experiments to explore geotechnical test equipment and techniques. Laboratory use of testing automation and electronic instrumentation. Experiments include data analysis, evaluation, and presentation.
Staff

1.38 Engineering Geology
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-1-8
Lecture: TR9-10.30 (1-371) Lab: TBA
______
Studies the effect of geologic features and processes on constructed facilities; interaction between the geologic environment and man-made structures, and human activities in general. Planning of subsurface exploration. Engineering geologic characterization of soil and rock, including joint surveys and aspects of sedimented and residual soils. Laboratory on basic geologic identification and mapping techniques. Extensive reading of case histories. Field trip.
H. H. Einstein
Textbooks (Fall 2016)

1.381 Rock Mechanics
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 1.38, 1.361
Units: 3-0-9
______
Introduces theoretical and experimental aspects of rock mechanics and prepares students for rock engineering. Includes review of laboratory and field testing; empirical and analytical methods for describing strength, deformability and conductivity of intact rock and rock masses; fracture mechanics and mechanics of discontinua, including flow through discontinua and hydraulic fracturing; and design and analysis of rock slopes and foundations on rock. Also discusses blasting design. Includes term paper/term project.
H. H. Einstein

1.383 Underground Construction
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 1.361, 1.38, or permission of instructor
Units: 3-0-6
______
Provides familiarization with the most important aspects of planning, analysis, design, and construction of underground structures in soil and rock. Covers detailed engineering analysis and design, and major aspects of construction techniques and construction planning. Discusses general planning and economic problems. Includes a major design project involving all aspects of underground construction.
H. H. Einstein

1.39 Independent Study in Geotechnical Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
For graduate students desiring further individual study of topics in geotechnical engineering.
Information: A. J. Whittle
No textbook information available

Construction Engineering and Management

1.462[J] Entrepreneurship in Construction and Real Estate Development
______

Graduate (Fall); second half of term
(Same subject as11.345[J])
Prereq: Permission of instructor
Units: 2-0-4
Begins Oct 24. Lecture: R3-5.30 (9-354)
______
Develops skills necessary to incubate concepts for new real estate/built environment ventures and to evolve those ideas into viable startup ventures. Addresses the progression of an idea, from inception to opportunity to sustainable business. Students develop a business plan. Guest lecturers share their entrepreneurial paths and relevant experience. Explores the role of real estate developers in developing/emerging markets, with a focus on solving social development challenges, innovating new development strategies/products, and generating triple bottom-line returns with development projects.
J. F. Kennedy
Textbooks (Fall 2016)

1.463[J] Globalization and the Built Environment
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as11.342[J])
Prereq: Permission of instructor
Units: 2-0-4
______
Addresses the importance and pervasiveness of globalization in Architecture, Engineering and Construction Companies (AEC Firms). Covers strategies for a presence in the global market and the importance of the global financial market in project financing, with a primary focus on infrastructure. Includes discussion of innovative approaches to marketing, partnering, risk management, finance, specialized delivery systems, and privatization.
F. Moavenzadeh, D. Wolff

1.472[J] Innovative Project Delivery in the Public and Private Sectors
______

Graduate (Spring); first half of term
(Same subject as11.344[J])
Prereq: Permission of instructor
Units: 2-0-4
______
Develops a strong strategic understanding of how best to deliver various types of projects in the built environment. Examines the compatibility of various project delivery methods, consisting of organizations, contracts, and award methods, with certain types of projects and owners. Six methods examined: traditional general contracting; construction management; multiple primes; design-build; turnkey; and build-operate-transfer. Includes lectures, case studies, guest speakers, and a team project to analyze a case example.
C. M. Gordon


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Produced: 29-SEP-2016 06:37 AMFall 2016 Course 1: Civil and Environmental Engineering
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Course 1: Civil and Environmental Engineering
Fall 2016


Materials and Structures

1.541 Mechanics and Design of Concrete Structures
______

Graduate (Fall)
(Subject meets with1.054)
Prereq: 1.035
Units: 3-0-9
Lecture: MW1-2.30 (1-246)
______
Studies strength and deformation of concrete under various states of stress; failure criteria; concrete plasticity; and fracture mechanics concepts. Topics include fundamental behavior of reinforced concrete structural systems and their members; basis for design and code constraints; high-performance concrete materials and their use in innovative design solutions; and yield line theory for slabs. Uses behavior models and nonlinear analysis. Covers complex systems, including bridge structures, concrete shells, and containments. Students taking graduate version complete additional assignments.
O. Buyukozturk
Textbooks (Fall 2016)

1.545 Atomistic Modeling and Simulation of Materials and Structures
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Covers multiscale atomistic modeling and simulation methods, with focus on mechanical properties (elasticity, plasticity, creep, fracture, fatigue) of a range of materials (metals, ceramics, proteins, biological materials, biomaterials). Topics include mechanics of materials (energy principles, nano-/micromechanics, deformation mechanisms, size effects, hierarchical biological structures) and atomistic modeling (chemistry, interatomic potentials, visualization, data analysis, numerical methods, supercomputing, algorithms). Includes an interactive computational project.
M. J. Buehler

1.546 Statistical Mechanics of Biological Systems
______

Not offered academic year 2016-2017Graduate (IAP)
Prereq: Permission of instructor
Units: 2-0-4
______
Develops the theory and methods of statistical mechanics of biological systems specifically relevant to environmental engineers. Intended for students with a background in biology, but without prior exposure to statistical mechanics.
E. Alm

1.56[J] Structural Mechanics in Nuclear Power Technology
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as2.084[J],22.314[J])
Prereq: 2.001 or permission of instructor
Units: 3-0-9
______
Structural components in nuclear power plant systems, their functional purposes, operating conditions, and mechanical/structural design requirements. Combines mechanics techniques with models of material behavior to determine adequacy of component design. Considerations include mechanical loading, brittle fracture, inelastic behavior, elevated temperatures, neutron irradiation, vibrations and seismic effects.
Staff

1.561 Motion-Based Design
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Presents a rational basis for the preliminary design of motion-sensitive structures. Topics include: analytical and numerical techniques for establishing the optimal stiffness distribution, the role of damping in controlling motion, tuned mass dampers, base isolation systems, and an introduction to active structural control. Examples illustrating the application of the motion-based design paradigm to building structures subjected to wind and seismic excitation are discussed.
Staff

1.562 Structural Design Project I
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Lecture: F2-5 (1-371)
______
Students work in teams to design a long-span structure, emphasizing conceptual design and advanced structural analysis. Subject covers structural systems and construction methods, interdisciplinary collaboration, design strategies for resistance to static and dynamic loading, and simplified calculation methods to validate numerical simulations. Emphasis on oral and visual communication of engineering concepts and students present their projects to leading engineers for feedback.
J. Ochsendorf, G. Herning
No textbook information available

1.563 Structural Design Project II
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Students work in teams to design a tall building, emphasizing the design of vertical load systems, lateral load systems, and floor systems. Uses studies of precedent buildings and metrics of structural performance including material efficiency and embodied carbon to evaluate multiple design concepts. Simplified calculation methods are validated with advanced numerical simulations. Formal presentations will be used to improve oral and visual communication.
J. Ochsendorf

1.57 Mechanics of Materials: An Energy Approach
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 1.050 or permission of instructor
Units: 3-2-7
______
An opportunity to update knowledge in continuum mechanics and constitutive behavior, and modeling of engineering materials based on thermodynamics of irreversible processes. Introduction to continuum mechanics and material modeling of engineering materials based on first energy principles: deformation and strain; momentum balance, stress, and stress states; elasticity and elasticity bounds; plasticity and yield design. Overarching theme is a unified mechanistic language using thermodynamics, which allows for understanding, modeling, and design of a broad range of engineering materials.
F. J. Ulm

1.570 Micromechanics and Durability of Solids
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 1.050, 1.57; or permission of instructor
Units: 3-0-9
______
Introduction to fracture mechanics, poromechanics and micromechanics using a unified mechanistic approach based on energy principles for modeling a large range of man-made and natural engineering material behavior. Energy release and fracture energy, stress intensity factors and toughness, saturated and partially saturated poromechanics of deformable porous materials, Darcy's law, linear micromechanics and application to porous materials, homogenization methods, chemomechanics of dissolution processes. In addition to assignments, emphasizes development of a consistent engineering science approach, culminating in a term paper.
F. J. Ulm

1.571 Modeling and Analysis of Structures
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Covers analytical and computer-based methods for the analysis of structural systems. Introduces strategies for the quantitative study of indeterminate and nonlinear structures. Topics provide insight into structural analysis software and the implementation of the finite element method. Emphasizes modeling complex structural behavior, such as elastic instability, local and global buckling, physical nonlinearity, geometric stiffness, and thermal expansion. Application examples cover a range of structural components and systems, with models and methods specific to the study of building frames, arches, shells, and cable-supported and tensile structures. Assignments provide experience with the construction of mathematical and finite element models, the derivation of closed-form solutions, and the effective use of structural analysis programs.
Staff

1.572 Structural Systems
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Designed to complement general structural analysis classes. Provides an understanding of the full range of structures and structural forms, including how they are designed and built. Develops skills necessary for conceptual design work, such as how to visualize options and judge their relative advantages in a qualitative manner. Case studies demonstrate how to conceive a structural form and consider its various options, and to understand assembly and construction methods intrinsic to the real behavior of the final structure.
Staff

1.573[J] Structural Mechanics
______

Graduate (Fall)
(Same subject as2.080[J])
Prereq: 2.002
Units: 4-0-8
URL: http://deslab.mit.edu/DesignLab/courses/13.10/1310.html
Lecture: MW2.30-4 (2-105) Recitation: F9 (3-442)
______
Presents fundamental concepts of structural mechanics with applications to marine, civil, and mechanical structures. Covers residual stresses; thermal effects; analysis of beams, columns, tensioned beams, trusses, frames, arches, cables, and shafts of general shape and material, including composites; elastic buckling of columns; exact and approximate methods, energy methods, principle of virtual work, and introduction to computational structural mechanics.
T. Wierzbicki, H. Schmidt
Textbooks (Fall 2016)

1.574[J] Analysis of Historic Structures
______

Graduate (Fall)
(Same subject as4.445[J])
(Subject meets with4.444)
Prereq: None
Units: 3-0-6
URL: http://architecture.mit.edu/subject/fall-2016-4444
Lecture: W2-5 (1-242)
______
Technical and historical study of structures in architecture and engineering. Focuses on the design and assessment of historic structures in masonry, timber, concrete, and metal. Course is driven by student research proposals. Previous student projects have researched Gothic flying buttresses, wooden covered bridges, Roman aqueducts, and iron train stations.
J. Ochsendorf
Textbooks (Fall 2016)

1.575[J] Computational Structural Design and Optimization
(New)
______

Graduate (Fall)
(Same subject as4.450[J])
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4450
Lecture: F9-12 (9-354) +final
______
Research seminar focusing on cutting-edge applications of computation for creative, early-stage structural design and optimization for architecture. Incorporates computational design fundamentals, including problem parameterization and formulation; design space exploration strategies, including interactive, heuristic, and gradient-based optimization; and computational structural analysis methods, including the finite element method, graphic statics, and approximation techniques. Case studies introduce and investigate a range of historical and contemporary examples of structural optimization in theory and practice.
C. Mueller
No textbook information available

1.581[J] Structural Dynamics and Vibrations
______

Graduate (Fall)
(Same subject as2.060[J],16.221[J])
(Subject meets with1.058)
Prereq: Permission of instructor
Units: 3-1-8
Lecture: MWF10 (1-390) Recitation: W4 (1-246)
______
Single- and multiple-degree-of-freedom vibration problems, using matrix formulation and normal mode superposition methods. Time and frequency domain solution techniques including convolution and Fourier transforms. Applications to vibration isolation, damping treatment, and dynamic absorbers. Analysis of continuous systems by exact and approximate methods. Applications to buildings, ships, aircraft and offshore structures. Vibration measurement and analysis techniques. Students should possess basic knowledge in structural mechanics and in linear algebra. Students taking graduate version complete additional assignments.
E. Kausel, J. K. Vandiver
No textbook information available

1.582 Design of Steel Structures
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Lecture: TR9.30-11 (1-379)
______
Provides ability to design and assess steel structures. Steel structures are taught at three levels: the overall structural system (multi-story buildings, wide-span buildings, bridges, masts, and towers); the components of a structural system (floor systems, plate girders, frames, and beams); and the details of structural components (connection types, welding, and bolting). Each level includes a balance among theoretical analysis, design requirements, and construction/cost considerations. Existing structures are used as worked examples.
J. Ochsendorf, G. Herning
Textbooks (Fall 2016)

1.589 Studies in Structural Design and Analysis
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Individual study of advanced subjects under staff supervision. Content arranged to suit the particular requirements of the student and interested members of the staff.
Information: O. Buyukozturk
No textbook information available

1.597 Studies in Construction Materials
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Advanced topics in construction materials selected by students for individual study with staff approval.
Information: O. Buyukozturk
No textbook information available

Hydrodynamics and Coastal Engineering

1.61 Transport Processes in the Environment
______

Graduate (Fall)
(Subject meets with1.061)
Prereq: 1.060B
Units: 3-1-8
Lecture: MWF10 (48-316) Recitation: F11 (48-316) +final
______
Introduces mass transport in environmental flows, with emphasis on river and lake systems. Covers derivation and solutions to the differential form of mass conservation equations. Topics include molecular and turbulent diffusion, boundary layers, dissolution, bed-water exchange, air-water exchange, and particle transport. Meets with 1.061A first half of term. Students taking graduate version complete additional assignments.
H. M. Nepf
No required or recommended textbooks

1.63[J] Advanced Fluid Dynamics
______

Graduate (Spring)
(Same subject as2.26[J])
Prereq: 18.085; 2.25 or permission of instructor.
Units: 4-0-8
URL: http://web.mit.edu/1.63/www/lecnote.html
______
Fundamentals of fluid dynamics intrinsic to natural physical phenomena and/or engineering processes. Discusses a range of topics and advanced problem-solving techniques. Sample topics include brief review of basic laws of fluid motion, scaling and approximations, creeping flows, boundary layers in high-speed flows, steady and transient, similarity method of solution, buoyancy-driven convection in porous media, dispersion in steady or oscillatory flows, physics and mathematics of linearized instability, effects of shear and stratification. In alternate years, two of the following modules will be offered: I: Geophysical Fluid Dynamics of Coastal Waters, II: Capillary Phenomena, III: Non-Newtonian Fluids, IV: Flagellar Swimming.
T. R. Akylas, G. H. McKinley, R. Stocker

1.631[J] Fluid Dynamics and Disease
______

Graduate (Spring)
(Same subject as2.250[J],HST.537[J])
Prereq: None
Units: 3-0-9
______
Reviews theoretical notions in mathematical epidemiology and open problems in understanding and modeling disease onset and spread. Bridges the disease modeling efforts at the large-scale population-level and those at the micro-scale pathogen-level via the use of fluid dynamics. Covers topics such as interfacial flows, fluid fragmentation, multiphase flows, turbulent flows, and fluid-structure interaction. Intended for students with a strong quantitative background interested in learning about applications in health and epidemiology and for students with an epidemiology and health background interested in learning about fluid dynamics approaches relevant to disease transmission. In the spirit of the OneHealth Initiative, covers advanced topics on the health of human, animal, and plant populations.
L. Bourouiba

1.64 Physical Limnology
______

Graduate (Spring)
Not offered regularly; consult department
(Subject meets with1.064)
Prereq: 1.061
Units: 3-0-9
______
Provides an introduction to physical processes occurring in lakes and shallow surface water systems with emphasis on mechanisms affecting fate and transport. Topics include internal waves, differential heating and cooling, boundary mixing, turbulent mixing, and influence of vegetation. Begins with a review of Navier-Stokes equation. Students taking graduate version complete additional assignments.
H. M. Nepf

1.66 Problems in Water Resources and Environmental Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Individual study in advanced topics as arranged between individual students and staff. Choice of subjects from theoretical, experimental, and practical phases of hydromechanics, hydraulic engineering, water resources, hydrology, and environmental engineering.
Staff
No textbook information available

1.67 Sediment Transport and Coastal Processes
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 1.061
Units: 4-0-8
______
Emphasizes the quantitative description of the mechanics of sediment transport in steady and unsteady flows based on hydrodynamic principles. Equations of motion for particles in a turbulent flow, entrainment, bedload, and suspended load. Bedform mechanics, ripples, and dunes. Flow resistance and boundary-layer mechanics for waves and combined wave-current flows. Wave-induced longshore currents, longshore and on-offshore sediment transport. Coastal protection.
Staff

1.685[J] Nonlinear Dynamics and Waves
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as2.034[J],18.377[J])
Prereq: Permission of instructor
Units: 3-0-9
______
A unified treatment of nonlinear oscillations and wave phenomena with applications to mechanical, optical, geophysical, fluid, electrical and flow-structure interaction problems. Nonlinear free and forced vibrations; nonlinear resonances; self-excited oscillations; lock-in phenomena. Nonlinear dispersive and nondispersive waves; resonant wave interactions; propagation of wave pulses and nonlinear Schrodinger equation. Nonlinear long waves and breaking; theory of characteristics; the Korteweg-de Vries equation; solitons and solitary wave interactions. Stability of shear flows. Some topics and applications may vary from year to year.
T. R. Akylas, R. R. Rosales

1.686[J] Nonlinear Dynamics and Turbulence
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as18.358[J])
(Subject meets with1.068)
Prereq: 18.355 or permission of instructor
Units: 3-0-9
______
Reviews theoretical notions of nonlinear dynamics, instabilities, and waves with applications in fluid dynamics. Discusses hydrodynamic instabilities leading to flow destabilization and transition to turbulence. Focuses on physical turbulence and mixing from homogenous isotropic turbulence. Also covers topics such as rotating and stratified flows as they arise in the environment, wave-turbulence, and point source turbulent flows. Students taking graduate version complete additional assignments.
L. Bourouiba

1.69 Introduction to Coastal Engineering
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 1.061
Units: 4-0-8
______
Basic dynamics of ocean surface waves; wave-driven, wind-driven, and tidal currents; boundary layers and sediment transport; and selected engineering applications. Formulation of the boundary-value problem for surface waves, linear plane-wave solution, shoaling, refraction, diffraction, statistical representation, and elements of nonlinearity. Depth-averaged formulation and selected solutions for sea level and currents driven by waves, winds, and tides. Elements of boundary layers, initial sediment motion, and bedload and suspended sediment transport. Alongshore sediment transport and shoreline change. Emphasizes basic principles, mathematical formulation and solution, and physical interpretation, with selected applications and exposure to current research.
J. Trowbridge

1.692[J] Ocean Wave Interaction with Ships and Offshore Energy Systems
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as2.24[J])
Prereq: 2.20, 18.085
Units: 4-0-8
______
Surface wave theory, conservation laws and boundary conditions, properties of regular surface waves and random ocean waves. Linearized theory of floating body dynamics, kinematic and dynamic free surface conditions, body boundary conditions. Simple harmonic motions. Diffraction and radiation problems, added mass and damping matrices. General reciprocity identities on diffraction and radiation. Ship wave resistance theory, Kelvin wake physics, ship seakeeping in regular and random waves. Discusses point wave energy absorbers, beam sea and head-sea devises, oscillating water column device and Well's turbine. Discusses offshore floating energy systems and their interaction with ambient waves, current and wind, including oil and gas platforms, liquefied natural gas (LNG) vessels and floating wind turbines. Homework drawn from real-world applications.
P. D. Sclavounos

1.699[J] Projects in Oceanographic Engineering
______

Graduate (Fall, Summer) Can be repeated for credit
(Same subject as2.689[J])
Prereq: Permission of instructor
Units arranged [P/D/F]
Meets at WHOI. TBA.
______
Projects in oceanographic engineering, carried out under supervision of Woods Hole Oceanographic Institution staff. Given at Woods Hole Oceanographic Institution.
J. Preisig, Woods Hole Staff
No textbook information available

Hydrology and Water Resource Systems

1.714 Surface Hydrology
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 1.070B or permission of instructor
Units: 3-0-9
______
Covers observations and theory of the physical processes involved in the hydrologic cycle. Processes considered are rainfall, infiltration, runoff generation, stream flow, evaporation, transpiration,and rainfall interception.
E. A. B. Eltahir

1.72 Groundwater Hydrology
______

Graduate (Fall)
(Subject meets with1.072)
Prereq: 1.061
Units: 3-1-8
Lecture: MW2.30-4 (48-308) Recitation: TBA +final
______
Presents the fundamentals of subsurface flow and transport, emphasizing the role of groundwater in the hydrologic cycle, the relation of groundwater flow to geologic structure, and the management of contaminated groundwater. Topics include Darcy equation, flow nets, mass conservation, the aquifer flow equation, heterogeneity and anisotropy, storage properties, regional circulation, unsaturated flow, recharge, stream-aquifer interaction, well hydraulics, flow through fractured rock, numerical models, groundwater quality, contaminant transport processes, dispersion, decay, and adsorption. Includes laboratory and computer demonstrations. Students taking graduate version complete additional assignments.
C. Harvey
No textbook information available

1.721 Advanced Subsurface Hydrology
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 1.72, 18.075, permission of instructor
Units: 3-0-9
______
Advanced treatment of solute transport in natural porous media with a focus on coupled chemical reaction and transport. Numerical modeling. Stochastic treatment of temporal and spatial variability. Mobile/immobile domain mass transfer, macrodispersion, tracer tests, salt water intrusion, heat transport.
C. Harvey

1.723 Computational Methods for Flow in Porous Media
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Covers physical, mathematical and simulation aspects of fluid flow and transport through porous media. Conservation equations for multiphase, multicomponent flow. Upscaling of parameters in heterogeneous fields. Modeling of viscous fingering and channeling. Numerical methods for elliptic equations: finite volume methods, multipoint flux approximations, mixed finite element methods, variational multiscale methods. Numerical methods for hyperbolic equations: low-order and high-order finite volume methods, streamline/front-tracking methods. Applications to groundwater contamination, oil and gas reservoir simulation, and geological CO2 sequestration, among others. Limited to graduate students.
R. Juanes

1.725 Chemicals in the Environment: Fate and Transport
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
______
For Institute students in all departments interested in the behavior of chemicals in the environment. Subject covers the movement of chemicals through water, air, and soil, and also addresses their eventual fate. Physical transport, as well as chemical and biological sources and sinks, are discussed. Emphasis on anthropogenic chemicals, though in the context of pre-existing natural chemical cycles. Linkages to health effects, sources and control, and policy aspects. Core requirement for Environmental MEng program.
H. Hemond

1.731 Water Resource Systems
______

Graduate (Fall)
(Subject meets with1.075)
Prereq: 1.070B or permission of instructor
Units: 3-0-9
Lecture: TR2.30-4 (48-316) +final
______
Surveys optimization and simulation methods for management of water resources. Case studies illustrate linear, quadratic, nonlinear programming and real-time control. Applications include river basin planning, irrigation and agriculture, reservoir operations, capacity expansion, assimilation of remote sensing data, and sustainable resource development. Students taking graduate version complete additional assignments.
D. McLaughlin
No textbook information available

1.74 Land, Water, Food, and Climate
______

Graduate (Spring)
Prereq: None
Units: 3-0-3
______
Seminar examines food production in a changing world, with an emphasis on key scientific questions about the connections between natural resources, climate, and agriculture. Students read and discuss papers on a range of topics, including water and land resources, climate change, demography, agro-ecology, biotechnology, trade, and food security. Provides a broad and balanced perspective on one of the defining global issues of this century. Considers scientific controversies as well as areas of general agreement and examines practical solutions for addressing critical problems. Participants present reviews of selected papers and lead follow-up discussions. They also have a role in shaping subject content.
D. McLaughlin

Aquatic Sciences, Water Quality Control, and Environmental Management

1.75 Limnology and Wetland Ecology
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Examines the major physical, chemical, and biological features of lakes and wetlands: basin geology, water budget, heat balance, thermal stratification, lake circulation, energy flow, biological communities, and cycles of major elements. Explores methodologies of limnology, including field methods and use of models, applications of modern sensor technology to lake and wetland studies and current issues in lake and wetland management.
H. F. Hemond

1.76 Aquatic Chemistry
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Chemistry (GIR) or 5.60
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Quantitative treatment of chemical processes in aquatic systems such as lakes, oceans, rivers, estuaries, groundwaters, and wastewaters. A brief review of chemical thermodynamics is followed by discussion of acid-base, precipitation-dissolution, coordination, and reduction-oxidation reactions. Emphasis is on equilibrium calculations as a tool for understanding the variables that govern the chemical composition of aquatic systems and the fate of inorganic pollutants.
B. Kocar

1.77 Water Quality Control
______

Graduate (Spring)
Prereq: 1.060B
Units: 3-0-9
______
Emphasizes mathematical models for predicting distribution and fate of effluents discharged into lakes, reservoirs, rivers, estuaries, and oceans. Focuses on formulation and structure of models as well as analytical and simple numerical solution techniques. Role of element cycles, such as oxygen, nitrogen, and phosphorus, as water quality indicators. Offshore outfalls and diffusion. Salinity intrusion in estuaries. Thermal stratification, eutrophication, and sedimentation processes in lakes and reservoirs.
E. E. Adams

1.78 Introduction to Soil Science
(New)
______

Graduate (Fall)
(Subject meets with1.078)
Prereq: None
Units: 3-1-8
Lecture: TR1-2.30 (48-308) Recitation: R4 (48-109) +final
______
Presents the physical, chemical, biological and genetic properties of soils, their global distribution, and response to management. Emphasizes factors controlling soil development, plant productivity, and the fate, cycling and bioavailability of soil nutrients and pollutants. Introduces Earth's different soil types and their classification; links characteristics with contemporary and historic issues surrounding natural and managed soil systems. Topics include soil carbon cycling, water and fertilizer management, and challenges associated with soil salinity-sodicity, erosion, and pollution. Includes field trips to local sites to examine soil physical properties, classification, and function. Introductory biology and chemistry are recommended prerequisites. Students taking graduate version complete additional assignments.
B. Kocar
Textbooks (Fall 2016)

1.801[J] Environmental Law, Policy, and Economics: Pollution Prevention and Control
______

Undergrad (Fall) HASS Social Sciences
(Same subject as11.021[J],17.393[J])
(Subject meets with1.811[J],11.630[J],IDS.430[J])
Prereq: None
Units: 3-0-9
Credit cannot also be received for15.663
Lecture: TR3.30-5 (E51-057) +final
______
Introduction to important issues in contemporary environmental law, policy, and economics. Discusses the roles and interactions of Congress, federal agencies, state governments, and the courts in dealing with environmental problems. Topics include common law, administrative law, environmental impact assessments required by the National Environmental Policy Act, and legislation and court decisions dealing with air pollution, water pollution, the control of hazardous waste, pollution and accident prevention, the production and use of toxic chemicals, community right-to-know, and environmental justice. Explores the role of science and economics in legal decisions, and economic incentives as an alternative or supplement to regulation. Analyzes pollution as an economic problem and a failure of markets. Introduction to basic legal skills: how to read and understand cases, regulation, and statutes; how to discover the current state of the law in a specific area; and how to take action toward resolution of environmental problems. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C. Caldart
Textbooks (Fall 2016)

1.802[J] Regulation of Chemicals, Radiation, and Biotechnology
______

Undergrad (Spring)
Not offered regularly; consult department
(Same subject as11.022[J])
(Subject meets with1.812[J],10.805[J],11.631[J],IDS.431[J],IDS.436[J])
Prereq: 1.801 or permission of instructor
Units: 3-0-9
______
Focuses on policy design and evaluation in the regulation of hazardous substances and processes. Includes risk assessment, industrial chemicals, pesticides, food contaminants, pharmaceuticals, radiation and radioactive wastes, product safety, workplace hazards, indoor air pollution, biotechnology, victims' compensation, and administrative law. Health and economic consequences of regulation, as well as its potential to spur technological change, are discussed for each regulatory regime. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C. Caldart

1.811[J] Environmental Law, Policy, and Economics: Pollution Prevention and Control
______

Graduate (Fall)
(Same subject as11.630[J],IDS.430[J])
(Subject meets with1.801[J],11.021[J],17.393[J])
Prereq: Permission of instructor for undergraduates
Units: 3-0-9
Credit cannot also be received for15.663
Lecture: TR3.30-5 (E51-057) +final
______
Reviews and analyzes federal and state regulation of air and water pollution, hazardous wastes, and the production and use of toxic chemicals. Analyzes pollution as an economic problem and the failure of markets. Emphasizes use of legal mechanisms and alternative approaches (such as economic incentives and voluntary approaches) to control pollution and to encourage chemical accident and pollution prevention. Focuses on the major federal legislation, the underlying administrative system, and the common law in analyzing environmental policy, economic consequences, and the role of the courts. Discusses classical pollutants and toxic industrial chemicals, community right-to-know, and environmental justice. Also provides an introduction to basic legal skills. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C. Caldart
Textbooks (Fall 2016)

1.812[J] Regulation of Chemicals, Radiation, and Biotechnology
______

Graduate (Spring)
Not offered regularly; consult department
(Same subject as11.631[J],IDS.431[J])
(Subject meets with1.802[J],10.805[J],11.022[J],IDS.436[J])
Prereq: 1.811 or permission of instructor
Units: 3-0-9
______
Focuses on policy design and evaluation in the regulation of hazardous substances and processes. Includes risk assessment, industrial chemicals, pesticides, food contaminants, pharmaceuticals, radiation and radioactive wastes, product safety, workplace hazards, indoor air pollution, biotechnology, victims' compensation, and administrative law. Health and economic consequences of regulation, as well as its potential to spur technological change, are discussed for each regulator regime. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C.Caldart

1.813[J] Technology, Globalization, and Sustainable Development
______

Graduate (Fall)
(Same subject as11.466[J],15.657[J],IDS.437[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: W EVE (4-6.30 PM) (E51-376)
______
Investigates sustainable development, taking a broad view to include not only a healthy economic base, but also a sound environment, stable employment, adequate purchasing power, distributional equity, national self-reliance, and maintenance of cultural integrity. Explores national, multinational, and international political and legal mechanisms to further sustainable development through transformation of the industrial state. Addresses the importance of technological innovation and the financial crisis of 2008.
N. Ashford
Textbooks (Fall 2016)

1.818[J] Sustainable Energy
______

Graduate (Fall)
(Same subject as2.65[J],10.391[J],11.371[J],22.811[J])
(Subject meets with2.650[J],10.291[J],22.081[J])
Prereq: Permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/10.391J/www/
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various energy technologies in each fuel cycle stage for fossil (oil, gas, synthetic), nuclear (fission and fusion) and renewable (solar, biomass, wind, hydro, and geothermal) energy types, along with storage, transmission, and conservation issues. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments.
M. W. Golay
Textbooks (Fall 2016)

1.819[J] Design for Sustainability
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as4.447[J])
Prereq: Permission of instructor
Units: 2-0-4
Subject Cancelled Subject Cancelled
______
Presents thought processes and quantitative tools, including life-cycle assessment (LCA) and the LEED and ENVSION rating systems, applicable to integrated design of buildings and horizontal infrastructure with the goal of minimizing the waste of materials, energy, and water. Readings, lectures, site visits, and assignments encourage systematic thinking and interdisciplinary collaboration to make sustainable design a reality. Includes a team project of students' choice, such as a conceptual design of a sustainable new building, a "green" retrofit, or a comparative LCA.
J. Ochsendorf

1.83 Environmental Organic Chemistry
______

Graduate (Fall)
(Subject meets with1.831)
Prereq: 5.60, 18.03
Units: 4-0-8
Lecture: MW1-2.30 (48-316) Recitation: F1 (48-316) +final
______
Focuses on the processes affecting organic compounds in the environment. Uses physical chemical properties to predict chemical transfers between environmental compartments (air, water, sediments, and biota). Uses molecular structure-reactivity relationships to estimate chemical, photochemical, and biochemical transformation rates. Resulting process models are combined to predict environmental concentrations (and related biological exposures) of anthropogenic and natural organic compounds.
P. M. Gschwend
No required or recommended textbooks

1.831 Environmental Organic Chemistry
______

Graduate (Fall)
(Subject meets with1.83)
Prereq: 5.60, 18.03
Units: 4-0-8
Lecture: MW1-2.30 (48-316) Recitation: F1 (48-316) +final
______
Focuses on the processes affecting organic compounds in the environment. Uses physical chemical properties to predict chemical transfers between environmental compartments (air, water, sediments, and biota). Uses molecular properties to estimate chemical, photochemical, and biochemical transformation rates. Resulting process models are combined to predict environmental concentrations (and related biological exposures) of anthropogenic and natural organic compounds.
P. M. Gschwend
No textbook information available

1.84[J] Atmospheric Chemistry
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as 10.817[J],12.807[J])
Prereq: 5.60
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Provides a detailed overview of the chemical transformations that control the abundances of key trace species in the Earth's atmosphere. Emphasizes the effects of human activity on air quality and climate. Topics include photochemistry, kinetics, and thermodynamics important to the chemistry of the atmosphere; stratospheric ozone depletion; oxidation chemistry of the troposphere; photochemical smog; aerosol chemistry; and sources and sinks of greenhouse gases and other climate forcers.
J. H. Kroll

1.841[J] Atmospheric Composition in the Changing Earth System
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as12.817[J])
Prereq: 1.84
Units: 3-0-9
______
Explores how atmospheric chemical composition both drives and responds to climate, with a particular focus on feedbacks via the biosphere. Topics include atmospheric nitrogen; DMS, sulfate, and CLAW; biogenic volatile organic compounds and secondary organic aerosol; wildfires and land use change; atmospheric methane and the oxidative capacity of the troposphere; and air quality and climate and geoengineering.
C. Heald

1.842[J] Aerosol and Cloud Microphysics and Chemistry
______

Graduate (Spring)
(Same subject as12.814[J])
(Subject meets with12.338)
Prereq: Permission of instructor
Units: 3-0-9
______
Focuses on understanding how aerosol particles form droplets or ice crystals during several atmospheric processes: determining Earth's radiative balance; heterogeneous chemistry and acid rain; understanding where, when and how much precipitation occurs. Provides tools for understanding the physics of aerosol and cloud element motion; the interaction of particles with water vapor, including phase changes and droplet and ice nucleation; the chemical composition of particles and the effect on cloud formation processes; and the effect of cloud processing on aerosol chemistry. Discusses relevant topics of contemporary interest, e.g., geoengineering and weather modification and volcanic effects. Students taking the graduate version complete different assignments.
D. Cziczo

1.851[J] Water, Sanitation, Hygiene and Environmental Sanitation (WASH-ENV) in Low- and Middle-income Countries
______

Graduate (Spring)
(Same subject as11.479[J])
Prereq: None
Units arranged
______
Addresses principles and practice of water, sanitation, hygiene and environmental sanitation (WASH-ENV) systems, infrastructure, engineering, and planning in low- and middle-income countries. Incorporates interdisciplinary technical, socio-cultural, public health, human rights, behavioral, and economic aspects into the design and implementation of interventions. Students develop skills to plan simple, yet reliable, WASH-ENV systems together with urban or rural communities that are compatible with local customs and available human and material resources.
Staff

1.86[J] Methods and Problems in Microbiology
______

Graduate (Fall)
(Same subject as7.492[J],20.445[J])
Prereq: None
Units: 3-0-9
Lecture: W EVE (3-6 PM) (4-146)
______
Students will read and discuss primary literature covering key areas of microbial research with emphasis on methods and approaches used to understand and manipulate microbes. Preference to first-year Microbiology and Biology students.
M. Laub
No required or recommended textbooks

1.87[J] Microbial Genetics and Evolution
______

Graduate (Fall)
(Same subject as7.493[J],12.493[J],20.446[J])
Prereq: 7.03, 7.05, or permission of instructor
Units: 4-0-8
Lecture: TR12.30-2.30 (66-160)
______
Covers aspects of microbial genetic and genomic analyses, central dogma, horizontal gene transfer, and evolution.
A. D. Grossman, G. Fournier
Textbooks (Fall 2016)

1.871 Computational Ecology
(New)
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Lecture: MW10.30-12
______
Using high-throughput genome sequencing data, covers how to reconstruct the short-term ecological and long-term evolutionary dynamics of biological communities and populations. Emphasizes computational tools central to modern microbial ecology. Topics include computational phylogenetics, population genomics, ecological metagenomics, and ecological interactions.
O. Cordero
No required or recommended textbooks

1.88 Physical Ecology at the Microscale
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Designed for students in fluid mechanics and engineering who want to explore applications of physics and fluids to biology and ecology, and for students in the biological sciences seeking to understand the physical constraints of life at the microscale. Topics include mass exchange and flow at the scale of microbes, motility and chemotaxis, encouter rates and predation, and small-scale turbulence. Emphasizes the application of physical and fluid dynamical principles to life at the microscale, in particular (but not limited to) aquatic systems.
Staff

1.89 Environmental Microbiology
______

Graduate (Spring)
(Subject meets with1.089)
Prereq: Biology (GIR)
Units: 3-0-9
______
Provides a general introduction to the diverse roles of microorganisms in natural and artificial environments. Topics include energetics, and growth; evolution and gene flow; population and community dynamics; water and soil microbiology; biogeochemical cycling; and microorganisms in biodeterioration and bioremediation. 7.014 recommended as prerequisite; students taking graduate version complete additional assignments. Meets with 1.089A first half of term.
M. Polz, O. Cordero

1.899 Career Reengineering Program and Professional Development Workshops
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 1-0-0 [P/D/F]
______
For students in the 10-month Career Reengineering Program sponsored by the School of Engineering. Limited to CRP fellows.
Staff

Special Studies

1.95[J] Teaching College-Level Science and Engineering
______

Graduate (Fall)
(Same subject as5.95[J],7.59[J],8.395[J],18.094[J])
(Subject meets with2.978)
Prereq: None
Units: 2-0-2 [P/D/F]
Lecture: R9-11 (4-149)
______
Participatory seminar focuses on the knowledge and skills necessary for teaching science and engineering in higher education. Topics include theories of adult learning; course development; promoting active learning, problemsolving, and critical thinking in students; communicating with a diverse student body; using educational technology to further learning; lecturing; creating effective tests and assignments; and assessment and evaluation. Students research and present a relevant topic of particular interest. Appropriate for both novices and those with teaching experience.
J. Rankin
No textbook information available

1.968 Graduate Studies in Civil and Environmental Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No textbook information available

1.969 Graduate Studies in Civil and Environmental Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Individual study, research, or laboratory investigations at the graduate level under faculty supervision.
Consult Department Academic Programs Office
No textbook information available

1.982 Research in Civil and Environmental Engineering
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
For research assistants in the department, when assigned research is not used for thesis but is approved for academic credit. Credit for this subject may not be used for any degree granted by Course 1.
Consult Department Academic Programs Office
No textbook information available

1.984 Teaching Experience in Civil and Environmental Engineering
______

Graduate (Fall, Spring)
Prereq: Permission of instructor
Units: 0-2-0
URL: http://cee.mit.edu/node/20160
TBA.
______
Provides classroom teaching experience under the supervision of faculty member(s). Students prepare instructional material, deliver lectures, grade assignments, and prepare a teaching portfolio to be submitted at the end of term. Concurrent enrollment in 1.95J strongly recommended. Enrollment limited by availability of suitable teaching assignments.
Information: Academic Program Office
No textbook information available

1.999 Undergraduate Studies in Civil and Environmental Engineering
______

Undergrad (Fall, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Individual study, research, or laboratory investigations under faculty supervision.
Consult Department Academic Programs Office
No textbook information available

1.EPE UPOP Engineering Practice Experience
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.EPE,2.EPE,3.EPE,6.EPE,10.EPE,16.EPE,22.EPE)
Prereq: 2.EPW or permission of instructor
Units: 0-0-1 [P/D/F]
TBA.
______
Provides sophomores with guided practice in finding opportunities and excelling in the world of practice. Building on the skills and relationships acquired in the Engineering Practice Workshop, students receive coaching to articulate goals, invoke the UPOP network of mentors and employers, identify and pursue opportunities and negotiate terms of their summer assignment. Students complete a 10-12 week internship, which includes filing three progress reports, conducting one informational interview, and possibly hosting a site visit by MIT staff. Returning to campus as juniors, UPOP students take part in reflective exercises that aid assimilation of learning objectives and reinforce the cognitive link between all aspects of the UPOP experience and disciplinary fields of study. Sequence begins in the spring of sophomore year and ends in the fall of junior year.
Staff
No textbook information available

1.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No textbook information available

1.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of an SM, MEng, CE, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member.
Consult Department Academic Programs Office
Textbooks arranged individually

1.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of an S.B. thesis; to be arranged by the student and an appropriate MIT faculty member. Intended for seniors. Student must submit an approved thesis proposal to the Academic Programs Office by the fifth week of the first term the student is registered for thesis.
Consult Department Academic Programs Office
Textbooks arranged individually

1.UR Research in Civil and Environmental Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually

1.URG Research in Civil and Environmental Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Individual research or laboratory study under faculty supervision. Also opportunities in ongoing research program.
Consult Department Academic Programs Office
Textbooks arranged individually

1.S82 Special Problems in Environmental Microbiology and Chemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Advanced study of topics not covered in the regular subject listings, particularly seminar, laboratory, and experimental subjects offered by permanent or visiting faculty. Addresses topics in environmental microbiology, ecological genomics, microbial evolution and population genetics, oceanography, biogeochemical processes, environmental organic chemistry and aquatic chemistry.
S. W. Chisholm, M. F. Polz, E. J. Alm, P. M. Gschwend, H. F. Hemond
No required or recommended textbooks

1.S977 Special Graduate Subject in Civil and Environmental Engineering
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Graduate subjects taught experimentally; subjects offered by visiting faculty; and seminars on topics of current interest not included in the regular curriculum. 1.978 is taught P/D/F.
Consult Department Academic Programs Office
No textbook information available

1.S978 Special Graduate Subject in Civil and Environmental Engineering
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of Instructor
Units arranged [P/D/F]
TBA.
______
No textbook information available

1.S979 Special Graduate Subject in Civil and Environmental Engineering
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
URL: https://learning-modules.mit.edu/class/index.html?uuid=/course/1/sp16/1.S979
TBA.
______
Graduate subjects taught experimentally; subjects offered by visiting faculty; and seminars on topics of current interest not included in the regular curriculum. 1.978 is taught P/D/F.
Consult Department Academic Programs Office
No textbook information available

1.S980 Special Graduate Subject in Civil and Environmental Engineering
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Graduate subjects taught experimentally; subjects offered by visiting faculty; and seminars on topics of current interest not included in the the regular curriculum. 1.978 is taught P/D/F/.
Staff
No textbook information available

1.S981 Special Graduate Subject in Civil and Environmental Engineering
______

Graduate (Fall, IAP, Spring, Summer); first half of term
Prereq: Permission of Instructor
Units arranged
TBA.
______
Graduate subjects taught experimentally; subjects offered by visiting faculty; and seminars on topics of current interest not included in the the regular curriculum. 1.S978 is taught P/D/F.
Staff
No textbook information available

1.S982 Special Graduate Subject in Civil and Environmental Engineering
______

Graduate (Fall, IAP, Spring, Summer); second half of term
Prereq: Permission of Instructor
Units arranged
TBA.
______
Graduate subjects taught experimentally; subjects offered by visiting faculty; and seminars on topics of current interest not included in the the regular curriculum. 1.S978 is taught P/D/F/.
Staff
No textbook information available

1.S991 Special Undergraduate Subject in Civil and Environmental Engineering
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No textbook information available

1.S992 Special Undergraduate Subject in Civil and Environmental Engineering
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Subjects taught experimentally; subjects offered by visiting faculty; and seminars on topics of current interest not included in the regular curriculum. 1.S991 is taught P/D/F.
Consult Department Academic Programs Office
No textbook information available

1.S993 Special Undergraduate Subject in Civil and Environmental Engineering
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: TR1 (1-242) Lab: F2-4 (1-050)
______
Subjects taught experimentally; subjects offered by visiting faculty; and seminars on topics of current interest not included in the regular curriculum. 1.S991 is taught P/D/F.
Consult Department Academic Programs Office
No required or recommended textbooks


left arrow|1.00-1.149|1.150-1.499|1.50-1.999 plus UROP and Thesis|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 2: Mechanical Engineering
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Course 2: Mechanical Engineering
Fall 2016


Freshman Year Introductory Subjects

2.00A[J] Fundamentals of Engineering Design: Explore Space, Sea and Earth
______

Undergrad (Spring)
Not offered regularly; consult department
(Same subject as16.00A[J])
Prereq: Physics I (GIR), Calculus I (GIR)
Units: 3-3-3
______
Student teams formulate and complete space/earth/ocean exploration-based design projects with weekly milestones. Introduces core engineering themes, principles, and modes of thinking. Specialized learning modules enable teams to focus on the knowledge required to complete their projects, such as machine elements, electronics, design process, visualization and communication. Includes exercises in written and oral communication and team building. Examples of projects include surveying a lake for millfoil, from a remote controlled aircraft, and then sending out robotic harvesters to clear the invasive growth; and exploration to search for the evidence of life on a moon of Jupiter, with scientists participating through teleoperation and supervisory control of robots. Enrollment limited; preference to freshmen.
A. H. Techet, D. Newman

2.00B Toy Product Design
______

Undergrad (Spring)
Prereq: None
Units: 3-5-1
______
Provides students with an overview of design for entertainment and play, as well as opportunities in creative product design and community service. Students develop ideas for new toys that serve clients in the community, and work in teams with local sponsors and with experienced mentors on a themed toy design project. Students enhance creativity and experience fundamental aspects of the product development process, including determining customer needs, brainstorming, estimation, sketching, sketch modeling, concept development, design aesthetics, detailed design, and prototyping. Includes written, visual, and oral communication. Enrollment limited; preference to freshmen.
D. R. Wallace

Core Undergraduate Subjects

2.00 Introduction to Design
______

Undergrad (Fall); second half of term
Prereq: None
Units: 2-2-2
Begins Oct 24. Lecture: MW3.30-5 (3-370) Lab: R2-5 (35-307) or F9.30-12.30 (35-307) or F2-5 (35-307)
______
Project-based introduction to product development and engineering design. Emphasizes key elements of the design process, including defining design problems, generating ideas, and building solutions. Presents a range of design techniques to help students think about, evaluate, and communicate designs, from sketching to physical prototyping, as well as other types of modeling. Students work both individually and in teams. Enrollment limited; preference to Course 2-A sophomores.
M. Yang
No required or recommended textbooks

2.001 Mechanics and Materials I
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Physics I (GIR);Coreq: 18.03 or 2.087
Units: 3-2-7
Lecture: TR11-12.30 (10-250) Lab: TBA Recitation: M9.30-11 (5-134) or M11-12.30 (5-217) or M2-3.30 (5-134) or M3.30-5 (5-217) or T9.30-11 (5-234) or T1-2.30 (5-233) or T2.30-4 (5-233) or T EVE (7-8.30 PM) (5-233) +final
______
Introduction to statics and the mechanics of deformable solids. Emphasis on the three basic principles of equilibrium, geometric compatibility, and material behavior. Stress and its relation to force and moment; strain and its relation to displacement; linear elasticity with thermal expansion. Failure modes. Application to simple engineering structures such as rods, shafts, beams, and trusses. Application to biomechanics of natural materials and structures.
G. Barbastathis, A. E. Hosoi, K. Kamrin
No required or recommended textbooks

2.002 Mechanics and Materials II
______

Undergrad (Spring)
Prereq: 2.001; Chemistry (GIR)
Units: 3-3-6
______
Introduces mechanical behavior of engineering materials, and the use of materials in mechanical design. Emphasizes the fundamentals of mechanical behavior of materials, as well as design with materials. Major topics: elasticity, plasticity, limit analysis, fatigue, fracture, and creep. Materials selection. Laboratory experiments involving projects related to materials in mechanical design. Enrollment may be limited due to laboratory capacity; preference to Course 2 majors and minors.
L. Anand, K. Kamrin, P. Reis

2.003[J] Dynamics and Control I
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
(Same subject as1.053[J])
Prereq: Physics II;Coreq: 18.03 or 2.087
Units: 4-1-7
Lecture: TR9.30-11 (10-250) Recitation: R12 (5-233) or R1 (5-233) or R3 (5-233) or R4 (5-233) or F2 (1-246) or F3 (1-246) +final
______
Introduction to the dynamics and vibrations of lumped-parameter models of mechanical systems. Kinematics. Force-momentum formulation for systems of particles and rigid bodies in planar motion. Work-energy concepts. Virtual displacements and virtual work. Lagrange's equations for systems of particles and rigid bodies in planar motion. Linearization of equations of motion. Linear stability analysis of mechanical systems. Free and forced vibration of linear multi-degree of freedom models of mechanical systems; matrix eigenvalue problems.
J. K. Vandiver, N. C. Makris, N. M. Patrikalakis, T. Peacock, D. Gossard, K. Turitsyn
No required or recommended textbooks

2.004 Dynamics and Control II
______

Undergrad (Fall, Spring)
Prereq: 2.003 or 2.03; Physics II (GIR)
Units: 4-2-6
Lecture: TR9.30-11,F11 (3-270) Lab: M1-3 (3-062) or M3-5 (3-062) or T1-3 (3-062) or T3-5 (3-062) +final
______
Modeling, analysis, and control of dynamic systems. System modeling: lumped parameter models of mechanical, electrical, and electromechanical systems; interconnection laws; actuators and sensors. Linear systems theory: linear algebra; Laplace transform; transfer functions, time response and frequency response, poles and zeros; block diagrams; solutions via analytical and numerical techniques; stability. Introduction to feedback control: closed-loop response; PID compensation; steady-state characteristics, root-locus design concepts, frequency-domain design concepts. Laboratory experiments and control design projects. Enrollment may be limited due to laboratory capacity; preference to Course 2 majors and minors.
G. Barbastathis, D. Del Vecchio, D. C. Gossard, D. E. Hardt, S. Lloyd
Textbooks (Fall 2016)

2.005 Thermal-Fluids Engineering I
______

Undergrad (Fall, Spring)
Prereq: Physics II (GIR), Calculus II (GIR); 2.086, 6.0002, or 18.06; or permission of instructor
Units: 5-0-7
Lecture: MW9-11 (1-190) Recitation: F11 (1-371) or F12 (1-371) or F1 (1-371) +final
______
Integrated development of the fundamental principles of thermodynamics, fluid mechanics, and heat transfer with applications. Focuses on the development of the first and second laws of thermodynamics with special consideration of the rate processes associated with heat transfer and work transfer. Entropy generation and its influence on the performance of engineering systems. Conduction heat transfer in solids including steady-state and transient situations. Finned surfaces. Coupled and uncoupled fluid models. Hydrostatics. Inviscid flow analysis and Bernoulli equation. Internal and external laminar viscous flows. Turbulence. Boundary layers. Head loss in pipes.
J. G. Brisson, J. Buongiorno, P. F. J. Lermusiaux, K. Varanasi
Textbooks (Fall 2016)

2.006 Thermal-Fluids Engineering II
______

Undergrad (Fall, Spring)
Prereq: 2.005; or 2.051, 2.06
Units: 5-0-7
Lecture: MW9.30-11,F9 (3-370) Recitation: F11 (1-242) or F1 (1-242) or F2 (1-242) +final
______
Focuses on the application of the principles of thermodynamics, heat transfer, and fluid mechanics to the design and analysis of engineering systems. Laminar and turbulent flow. Heat transfer associated with laminar and turbulent flow of fluids in free and forced convection in channels and over surfaces. Pure substance model. Heat transfer in boiling and condensation. Thermodynamics and fluid mechanics of steady flow components of thermodynamic plants. Heat exchanger design. Power cycles and refrigeration plants. Design of thermodynamic plants. Radiation heat transfer. Multi-mode heat transfer and fluid flow in thermodynamic plants.
J. G. Brisson, A. E. Hosoi, R. Karnik, G. H. McKinley
Textbooks (Fall 2016)

2.007 Design and Manufacturing I
______

Undergrad (Spring)
Prereq: 2.001; 2.670;Coreq: 2.086
Units: 3-4-5
______
Develops students' competence and self-confidence as design engineers. Emphasis on the creative design process bolstered by application of physical laws. Instruction on how to complete projects on schedule and within budget. Robustness and manufacturability are emphasized. Subject relies on active learning via a major design-and-build project. Lecture topics include idea generation, estimation, concept selection, visual thinking, computer-aided design (CAD), mechanism design, machine elements, basic electronics, technical communication, and ethics. Lab fee. Limited enrollment. Pre-registration required for lab assignment; special sections by lottery only.
D. Frey, S. Kim, A. Winter

2.008 Design and Manufacturing II
______

Undergrad (Fall, Spring) 1/2 Institute Lab
Prereq: 2.007 orCoreq: 2.017; 2.005 or 2.051
Units: 3-3-6
Lecture: MW11-12.30 (4-270) Lab: M2-5 (35-520) or T9-12 (35-308) or T2-5 (35-308) or W2-5 (35-520) or R9-12 (35-308) or R2-5 (35-308)
______
Integration of design, engineering, and management disciplines and practices for analysis and design of manufacturing enterprises. Emphasis is on the physics and stochastic nature of manufacturing processes and systems, and their effects on quality, rate, cost, and flexibility. Topics include process physics and control, design for manufacturing, and manufacturing systems. Group project requires design and fabrication of parts using mass-production and assembly methods to produce a product in quantity. Six units may be applied to the General Institute Lab Requirement. Enrollment may be limited due to laboratory capacity; preference to Course 2 majors and minors.
J.-H. Chun, M. L. Culpepper, S. Kim, S. G. Kim, S. E. Sarma, J. Hart
Textbooks (Fall 2016)

2.009 The Product Engineering Process
______

Undergrad (Fall)
Prereq: 2.001; 2.003 or 2.03; 2.005 or 2.051; 2.670, 2.678 or 2.00B
Units: 3-3-6
URL: http://web.mit.edu/2.009/www/
Lecture: MWF1 (10-250) Lab: T2-5 (3-037A) or T2-5 (3-037B) or T EVE (7-10 PM) (3-037A) or T EVE (7-10 PM) (3-037B) or T EVE (7-10 PM) (3-037C) or T EVE (7-10 PM) (3-037D) or W2-5 (3-037A) or W2-5 (3-037B) or W2-5 (3-037C) or W2-5 (3-037D) or W EVE (7-10 PM) (3-037A) or W EVE (7-10 PM) (3-037B) or R9-12 (3-037A) or R9-12 (3-037B) or R2-5 (3-037A) or R2-5 (3-037B)
______
Students develop an understanding of product development phases and experience working in teams to design and construct high-quality product prototypes. Design process learned is placed into a broader development context. Primary goals are to improve ability to reason about design alternatives and apply modeling techniques appropriate for different development phases; understand how to gather and process customer information and transform it into engineering specifications; and use teamwork to resolve the challenges in designing and building a substantive product prototype. Instruction and practice in oral communication provided. Enrollment may be limited due to laboratory capacity; preference to Course 2 seniors.
D. R. Wallace
Textbooks (Fall 2016)

2.013 Engineering Systems Design
______

Undergrad (Fall)
Prereq: 2.001; 2.003 or 2.03; 2.005 or 2.051; 2.670, 2.678 or 2.00B
Units: 0-6-6
Lecture: TR2.30-5 (NE45-202)
______
Focuses on the design of engineering systems to satisfy stated performance, stability, and/or control requirements. Emphasizes individual initiative, application of fundamental principles, and the compromises inherent in the engineering design process. Culminates in the design of an engineering system, typically a vehicle or other complex system. Includes instruction and practice in written and oral communication through team presentations, design reviews, and written reports. Enrollment may be limited due to laboratory capacity; preference to Course 2 majors and minors.
D. Hart
No required or recommended textbooks

2.014 Engineering Systems Development
______

Undergrad (Spring) Can be repeated for credit
Prereq: 2.001; 2.003 or 2.03; 2.005 or 2.051; 2.670, 2.678 or 2.00B
Units: 0-6-6
______
Focuses on implementation and operation of engineering systems. Emphasizes system integration and performance verification using methods of experimental inquiry. Students refine their subsystem designs and the fabrication of working prototypes. Includes experimental analysis of subsystem performance and comparison with physical models of performance and with design goals. Component integration into the full system, with detailed analysis and operation of the complete vehicle in the laboratory and in the field. Includes written and oral reports. Students carry out formal reviews of the overall system design. Instruction and practice in oral and written communication provided. Enrollment may be limited due to laboratory capacity; preference to Course 2 majors and minors.
D. Hart

2.016 Hydrodynamics
______

Undergrad (Fall)
Prereq: 2.001
Units: 4-2-6
Lecture: TR11-12.30 (3-442) Recitation: T3 (5-134) or W4 (5-134)
______
Principles of conservation of mass, momentum and energy in fluid mechanics. Basic geophysical fluid mechanics, including the effects of salinity, temperature, and density; heat balance in the ocean; large scale flows. Hydrostatics. Linear free surface waves, wave forces on floating and submerged structures. Added mass, lift and drag forces. Introduction to ocean acoustics; sound propagation and refraction. Sonar equation. Laboratory sessions in wave propagation, lift and drag forces on submerged bodies, and sound propagation. Meets with 2.06 first half of term.
A. H. Techet, P. D. Sclavounos
Textbooks (Fall 2016)

2.017[J] Design of Electromechanical Robotic Systems
______

Undergrad (Spring) 1/2 Institute Lab
(Same subject as1.015[J])
Prereq: 2.003 or 2.03;Coreq: 2.005, 2.05 and 2.051, or 2.016; 2.671
Units: 3-3-6
______
Design, construction, and testing of field robotic systems, through team projects with each student responsible for a specific subsystem. Projects focus on electronics, instrumentation, and machine elements. Design for operation in uncertain conditions is a focus point, with ocean waves and marine structures as a central theme. Basic statistics, linear systems, Fourier transforms, random processes, spectra and extreme events with applications in design. Lectures on ethics in engineering practice included. Enrollment may be limited due to laboratory capacity.
F. S. Hover, J. J. Leonard

2.019 Design of Ocean Systems
______

Undergrad (Spring)
Prereq: 2.001; 2.003; 2.005 or 2.016
Units: 3-3-6
______
Complete cycle of designing an ocean system using computational design tools for the conceptual and preliminary design stages. Team projects assigned, with each student responsible for a specific subsystem. Lectures cover hydrodynamics; structures; power and thermal aspects of ocean vehicles, environment, materials, and construction for ocean use; generation and evaluation of design alternatives. Focus on innovative design concepts chosen from high-speed ships, submersibles, autonomous vehicles, and floating and submerged deep-water offshore platforms. Lectures on ethics in engineering practice included. Instruction and practice in oral and written communication provided. Enrollment may be limited due to laboratory capacity; preference to Course 2 seniors.
C. Chryssostomidis, M. S. Triantafyllou

2.02A Engineering Materials: Properties and Applications
______

Undergrad (Fall); first half of term
Prereq: 2.001
Units: 2-0-4
Ends Oct 21. Lecture: TR11-12.30 (3-333) Recitation: W2-3.30 (5-234)
______
Introduction to the physical mechanisms that give rise to mechanical properties of engineering materials: stiffness, creep, stress-relaxation, strength, fracture-toughness, and fatigue. Also covers materials selection for mechanical design. Includes case studies on materials-limited problems in engineering design.
A. Kolpak
Textbooks (Fall 2016)

2.03 Dynamics I
______

Undergrad (Fall, Spring); first half of term
Prereq: Physics II;Coreq: 18.03 or 2.087
Units: 2-0-4
Ends Oct 21. Lecture: TR9.30-11 (10-250) Recitation: R12 (5-233) or R1 (5-233) or R3 (5-233) or R4 (5-233) or F2 (1-246) or F3 (1-246)
______
Introduction to the dynamics of one and two degree-of-freedom mechanical systems. Kinematics. Force-momentum formulation for particles and rigid bodies. Work-energy concepts. Rotation of rigid bodies, angular momentum, torques and moments of inertia. Newton, Euler equations (direct method in dynamics). Conservation laws in dynamics. Basics of equilibrium, linearization and stability analysis. Includes MATLAB modeling of dynamical systems with applications. Meets with 2.003 first half of term.
D. Gossard, K. Turitsyn, T. Peacock
No required or recommended textbooks

2.031 Dynamics II
______

Undergrad (Fall, Spring); second half of term
Prereq: 2.03
Units: 2-0-4
Begins Oct 24. Lecture: TR9.30-11 (10-250) Recitation: R12 (5-233) or R1 (5-233) or R3 (5-233) or R4 (5-233) or F2 (1-246) or F3 (1-246) +final
______
Continuation of topics introduced in 2.03, including work-energy concepts, Lagrange's equations for systems of particles and rigid bodies in planar motion, and matrix eigenvalue problems. Meets with 2.003 second half of term.
D. Gossard, K. Turitsyn, T. Peacock
No required or recommended textbooks

2.04A Systems and Controls
______

Undergrad (Spring); second half of term
Prereq: None.Coreq: 2.03
Units: 2-1-3
______
Introduction to linear systems, transfer functions, and Laplace transforms. Covers stability and feedback, and provides basic design tools for specifications of transient response. Briefly covers frequency-domain techniques. Enrollment may be limited due to laboratory capacity.
G. Barbastathis

2.04B Introduction to Mechanical Vibration
______

Not offered academic year 2016-2017Undergrad (Fall); second half of term
Prereq: 2.03, 2.086
Units: 2-1-3
______
Analyzes the time domain response of single- and multiple-degree-of-freedom (DOF) systems to initial conditions and force inputs. Uses matrix formulation of multiple-DOF problems, including finding natural frequencies and mode shapes. Provides an introduction to the method of normal mode superposition. Includes transfer function analysis of the response of linear systems to steady state harmonic inputs, with application to vibration isolation and dynamic absorbers. Also includes application to the analysis of machines with rotating imbalances. Enrollment may be limited due to lab capacity; preference to Course 2 majors and minors.
J. K. Vandiver

2.05 Thermodynamics
______

Undergrad (Fall); first half of term
Prereq: 2.001
Units: 3-0-3
Ends Oct 21. Lecture: MW9.30-11 (3-270) Recitation: W1 (3-442) or W2 (3-442) or W3 (3-442) or W4 (3-442)
______
Provides an introduction to thermodynamics, including first law (coupled and uncoupled systems, incompressible liquid, ideal gas) and second law (equilibrium, reversibility and irreversibility). Explores systems in communication with heat reservoirs; quasi-static processes; and heat engines and refrigeration. Properties of open systems, including mass, energy and entropy transfer.
C. Buie
Textbooks (Fall 2016)

2.051 Introduction to Heat Transfer
______

Undergrad (Fall); second half of term
Prereq: 2.05
Units: 2-0-4
Begins Oct 24. Lecture: MW9.30-11 (3-270) +final
______
Introduces fundamental processes of heat transfer. Fourier's law. Heat conduction processes including thermal resistance, lumped capacitance, fins, and the heat equation. Elementary convection, including laminar and turbulent boundary layers, internal flow, and natural convection. Thermal radiation, including Stefan-Boltzmann law, small object in large enclosure, and parallel plates. Basic concepts of heat exchangers.
J. H. Lienhard, E. N. Wang, A. Hosoi
No required or recommended textbooks

2.06 Fluid Dynamics
______

Undergrad (Fall, Spring); first half of term
Prereq: 2.001
Units: 2-0-4
Ends Oct 21. Lecture: TR11-12.30 (3-442) Recitation: T3 (5-134) or W4 (5-134)
______
Introduction to principal concepts and methods of fluid mechanics. Pressure, hydrostatics, and buoyancy. Control volume analysis. Mass conservation and momentum conservation for moving fluids. Viscous fluid flows, flow through pipes. Dimensional analysis. Boundary layers, and lift and drag on objects. Meets with 2.016 first half of fall term. Also offered second half of spring term.
G. H. McKinley, K. Varanasi, A. Techet
Textbooks (Fall 2016)

2.086 Numerical Computation for Mechanical Engineers
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Physics I (GIR), Calculus II (GIR);Coreq: 18.03 or 2.087
Units: 1-3-8
1st mtg Sep 7. Room TBA. Lecture: M1 (26-100) Lab: M9-12 (W31-301) or M2-5 (1-115) or T2-5 (W31-301) or W2-5 (1-115) or F9-12 (W31-301) or F2-5 (1-115) +final
______
Covers elementary programming concepts, including variable types, data structures, and flow control. Provides an introduction to linear algebra and probability. Numerical methods relevant to MechE, including approximation (interpolation, least squares, and statistical regression), integration, solution of linear and nonlinear equations, and ordinary differential equations. Presents deterministic and probabilistic approaches. Uses examples from MechE, particularly from robotics, dynamics, and structural analysis. Assignments require MATLAB programming. Enrollment may be limited due to laboratory capacity; preference to Course 2 majors and minors.
N. Hadjiconstantinou, A. Patera, D. Frey, A. Hosoi
No textbook information available

2.087 Engineering Mathematics: Linear Algebra and ODEs
______

Undergrad (Fall, Spring); first half of term
Prereq: Calculus II (GIR), Physics I (GIR)
Units: 2-0-4
Ends Oct 21. Lecture: MW9.30-11 (3-333) Recitation: M2-3.30 (1-242)
______
Introduction to linear algebra and ordinary differential equations (ODEs), including general numerical approaches to solving systems of equations. Linear systems of equations, existence and uniqueness of solutions, Gaussian elimination. Initial value problems, 1st and 2nd order systems, forward and backward Euler, RK4. Eigenproblems, eigenvalues and eigenvectors, including complex numbers, functions, vectors and matrices.
A. Hosoi, T. Peacock
Textbooks (Fall 2016)

Dynamics and Acoustics

2.032 Dynamics
______

Graduate (Fall)
Prereq: 2.003
Units: 4-0-8
URL: http://web.mit.edu/2.032/www/
Lecture: MW1-2.30 (3-370) Recitation: T4 (1-371)
______
Review of momentum principles. Hamilton's principle and Lagrange's equations. Three-dimensional kinematics and dynamics of rigid bodies. Study of steady motions and small deviations therefrom, gyroscopic effects, causes of instability. Free and forced vibrations of lumped-parameter and continuous systems. Nonlinear oscillations and the phase plane. Nonholonomic systems. Introduction to wave propagation in continuous systems.
T. R. Akylas, T. Peacock, N. Hadjiconstantinou
No required or recommended textbooks

2.034[J] Nonlinear Dynamics and Waves
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as1.685[J],18.377[J])
Prereq: Permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/2.034/www/
______
A unified treatment of nonlinear oscillations and wave phenomena with applications to mechanical, optical, geophysical, fluid, electrical and flow-structure interaction problems. Nonlinear free and forced vibrations; nonlinear resonances; self-excited oscillations; lock-in phenomena. Nonlinear dispersive and nondispersive waves; resonant wave interactions; propagation of wave pulses and nonlinear Schrodinger equation. Nonlinear long waves and breaking; theory of characteristics; the Korteweg-de Vries equation; solitons and solitary wave interactions. Stability of shear flows. Some topics and applications may vary from year to year.
T. R. Akylas, R. R. Rosales

2.036[J] Nonlinear Dynamics and Chaos
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as18.385[J])
Prereq: 18.03 or 18.034
Units: 3-0-9
URL: http://math.mit.edu/classes/18.385
Lecture: TR11-12.30 (2-136)
______
Introduction to the theory of nonlinear dynamical systems with applications from science and engineering. Local and global existence of solutions, dependence on initial data and parameters. Elementary bifurcations, normal forms. Phase plane, limit cycles, relaxation oscillations, Poincare-Bendixson theory. Floquet theory. Poincare maps. Averaging. Near-equilibrium dynamics. Synchronization. Introduction to chaos. Universality. Strange attractors. Lorenz and Rossler systems. Hamiltonian dynamics and KAM theory. Uses MATLAB computing environment.
R. R. Rosales
Textbooks (Fall 2016)

2.050[J] Nonlinear Dynamics: Chaos
______

Undergrad (Fall)
(Same subject as12.006[J],18.353[J])
Prereq: 18.03 or 18.034; Physics II (GIR)
Units: 3-0-9
Lecture: TR1-2.30 (2-105)
______
Introduction to nonlinear dynamics and chaos in dissipative systems. Forced and parametric oscillators. Phase space. Periodic, quasiperiodic, and aperiodic flows. Sensitivity to initial conditions and strange attractors. Lorenz attractor. Period doubling, intermittency, and quasiperiodicity. Scaling and universality. Analysis of experimental data: Fourier transforms, Poincare sections, fractal dimension, and Lyapunov exponents. Applications to mechanical systems, fluid dynamics, physics, geophysics, and chemistry. See 12.207J/18.354J for Nonlinear Dynamics: Continuum Systems.
P-T. Brun
Textbooks (Fall 2016)

2.060[J] Structural Dynamics and Vibrations
______

Graduate (Fall)
(Same subject as1.581[J],16.221[J])
(Subject meets with1.058)
Prereq: Permission of instructor
Units: 3-1-8
Lecture: MWF10 (1-390) Recitation: W4 (1-246)
______
Single- and multiple-degree-of-freedom vibration problems, using matrix formulation and normal mode superposition methods. Time and frequency domain solution techniques including convolution and Fourier transforms. Applications to vibration isolation, damping treatment, and dynamic absorbers. Analysis of continuous systems by exact and approximate methods. Applications to buildings, ships, aircraft and offshore structures. Vibration measurement and analysis techniques. Students should possess basic knowledge in structural mechanics and in linear algebra. Students taking graduate version complete additional assignments.
E. Kausel, J. K. Vandiver
No textbook information available

2.062[J] Wave Propagation
______

Graduate (Spring)
(Same subject as1.138[J],18.376[J])
Prereq: 2.003, 18.075
Units: 3-0-9
URL: http://math.mit.edu/classes/18.376/
______
Theoretical concepts and analysis of wave problems in science and engineering with examples chosen from elasticity, acoustics, geophysics, hydrodynamics, blood flow, nondestructive evaluation, and other applications. Progressive waves, group velocity and dispersion, energy density and transport. Reflection, refraction and transmission of plane waves by an interface. Mode conversion in elastic waves. Rayleigh waves. Waves due to a moving load. Scattering by a two-dimensional obstacle. Reciprocity theorems. Parabolic approximation. Waves on the sea surface. Capillary-gravity waves. Wave resistance. Radiation of surface waves. Internal waves in stratified fluids. Waves in rotating media. Waves in random media.
T. R. Akylas, R. R. Rosales

2.065 Acoustics and Sensing
______

Undergrad (Spring)
(Subject meets with2.066)
Prereq: 2.003, 2.04B, 6.003, 8.03, or 16.003
Units: 3-0-9
______

2.066 Acoustics and Sensing
______

Graduate (Spring)
(Subject meets with2.065)
Prereq: 2.003, 2.04B, 6.003, 8.03, 16.003, or permission of instructor
Units: 3-0-9
______
Introduces the fundamental concepts of acoustics and sensing with waves. Provides a unified theoretical approach to the physics of image formation through scattering and wave propagation in sensing. The linear and nonlinear acoustic wave equation, sources of sound, including musical instruments. Reflection, refraction, transmission and absorption. Bearing and range estimation by sensor array processing, beamforming, matched filtering, and focusing. Diffraction, bandwidth, ambient noise and reverberation limitations. Scattering from objects, surfaces and volumes by Green's Theorem. Forward scatter, shadows, Babinet's principle, extinction and attenuation. Ray tracing and waveguides in remote sensing. Applications to acoustic, radar, seismic, thermal and optical sensing and exploration. Students taking the graduate version of the subject complete additional assignments.
N. C. Makris

Solid Mechanics and Materials

2.071 Mechanics of Solid Materials
______

Graduate (Spring)
Prereq: 2.002 or 2.02A
Units: 4-0-8
______
Fundamentals of solid mechanics applied to the mechanical behavior of engineering materials. Kinematics of deformation, stress, and balance principles. Isotropic linear elasticity and isotropic linear thermal elasticity. Variational and energy methods. Linear viscoelasticity. Small-strain elastic-plastic deformation. Mechanics of large deformation; nonlinear hyperelastic material behavior. Foundations and methods of deformable-solid mechanics, including relevant applications. Provides base for further study and specialization within solid mechanics, including continuum mechanics, computational mechanics (e.g., finite-element methods), plasticity, fracture mechanics, structural mechanics, and nonlinear behavior of materials.
L. Anand, D. M. Parks

2.072 Mechanics of Continuous Media
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 2.071
Units: 3-0-9
______
Principles and applications of continuum mechanics. Kinematics of deformation. Thermomechanical conservation laws. Stress and strain measures. Constitutive equations including some examples of their microscopic basis. Solution of some basic problems for various materials as relevant in materials science, fluid dynamics, and structural analysis. Inherently nonlinear phenomena in continuum mechanics. Variational principles.
L. Anand

2.073 Solid Mechanics: Plasticity and Inelastic Deformation
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 2.071
Units: 3-0-9
Lecture: MW2.30-4 (1-150)
______
Physical basis of plastic/inelastic deformation of solids; metals, polymers, granular/rock-like materials. Continuum constitutive models for small and large deformation of elastic-(visco)plastic solids. Analytical and numerical solution of selected boundary value problems. Applications to deformation processing of metals.
L. Anand, D. M. Parks
No textbook information available

2.074 Solid Mechanics: Elasticity
______

Graduate (Fall)
Prereq: 2.002, 18.03
Units: 3-0-9
Lecture: MW11-12.30 (1-150) +final
______
Introduction to the theory and applications of elastic solids. Review strain, stress, and stress-strain law. Several of the following topics: Anisotropic material behavior. Piezoelectric materials. Effective properties of composites. Structural mechanics of beams and plates. Energy methods for structures. Two-dimensional problems. Stress concentration at cavities, concentrated loads, cracks, and dislocations. Variational methods and their applications; introduction to the finite element method. Introduction to wave propagation.
R. Abeyaratne
No required or recommended textbooks

2.076[J] Mechanics of Heterogeneous Materials
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as16.223[J])
Prereq: 2.002, 3.032, 16.20, or permission of instructor
Units: 3-0-9
______
Mechanical behavior of heterogeneous materials such as thin-film microelectro- mechanical systems (MEMS) materials and advanced filamentary composites, with particular emphasis on laminated structural configurations. Anisotropic and crystallographic elasticity formulations. Structure, properties and mechanics of constituents such as films, substrates, active materials, fibers, and matrices including nano- and micro-scale constituents. Effective properties from constituent properties. Classical laminated plate theory for modeling structural behavior including extrinsic and intrinsic strains and stresses such as environmental effects. Introduction to buckling of plates and nonlinear (deformations) plate theory. Other issues in modeling heterogeneous materials such as fracture/failure of laminated structures.
B. L. Wardle, S-G. Kim

2.080[J] Structural Mechanics
______

Graduate (Fall)
(Same subject as1.573[J])
Prereq: 2.002
Units: 4-0-8
Lecture: MW2.30-4 (2-105) Recitation: F9 (3-442)
______
Presents fundamental concepts of structural mechanics with applications to marine, civil, and mechanical structures. Covers residual stresses; thermal effects; analysis of beams, columns, tensioned beams, trusses, frames, arches, cables, and shafts of general shape and material, including composites; elastic buckling of columns; exact and approximate methods, energy methods, principle of virtual work, and introduction to computational structural mechanics.
T. Wierzbicki, H. Schmidt
Textbooks (Fall 2016)

2.081[J] Plates and Shells: Static and Dynamic Analysis
______

Graduate (Spring)
(Same subject as16.230[J])
Prereq: 2.071, 2.080, or permission of instructor
Units: 3-1-8
______
Stress-strain relations for plate and shell elements. Differential equations of equilibrium. Energy methods and approximate solutions. Bending and buckling of rectangular plates. Post-buckling and ultimate strength of cold formed sections and typical stiffened panels used in aerospace, civil, and mechanical engineering; offshore technology; and ship building. Geometry of curved surfaces. General theory of elastic, axisymmetric shells and their equilibrium equations. Buckling, crushing and bending strength of cylindrical shells with applications. Propagation of 1-D elastic waves in rods, geometrical and material dispersion. Plane, Rayleigh surface, and 3-D waves. 1-D plastic waves. Response of plates and shells to high-intensity loads. Dynamic plasticity and fracture. Application to crashworthiness and impact loading of structures.
T. Sapsis

2.082 Ship Structural Analysis and Design
______

Graduate (Spring); second half of term
Prereq: 2.081, 2.701
Units: 3-0-3
______
Design application of analysis developed in 2.081J. Ship longitudinal strength and hull primary stresses. Ship structural design concepts. Design limit states including plate bending, column and panel buckling, panel ultimate strength, and plastic analysis. Matrix stiffness, and introduction to finite element analysis. Computer projects on the structural design of a midship module.
R. S. McCord, T. Wierzbicki

2.084[J] Structural Mechanics in Nuclear Power Technology
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as1.56[J],22.314[J])
Prereq: 2.001 or permission of instructor
Units: 3-0-9
______
Structural components in nuclear power plant systems, their functional purposes, operating conditions, and mechanical/structural design requirements. Combines mechanics techniques with models of material behavior to determine adequacy of component design. Considerations include mechanical loading, brittle fracture, inelastic behavior, elevated temperatures, neutron irradiation, vibrations and seismic effects.
Staff

Computational Engineering

2.089[J] Computational Geometry
______

Graduate (Spring)
Not offered regularly; consult department
(Same subject as1.128[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Topics in surface modeling: b-splines, non-uniform rational b-splines, physically based deformable surfaces, sweeps and generalized cylinders, offsets, blending and filleting surfaces. Non-linear solvers and intersection problems. Solid modeling: constructive solid geometry, boundary representation, non-manifold and mixed-dimension boundary representation models, octrees. Robustness of geometric computations. Interval methods. Finite and boundary element discretization methods for continuum mechanics problems. Scientific visualization. Variational geometry. Tolerances. Inspection methods. Feature representation and recognition. Shape interrogation for design, analysis, and manufacturing. Involves analytical and programming assignments.
N. M. Patrikalakis, D. C. Gossard

2.091[J] Software and Computation for Simulation
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as1.124[J])
Prereq: 1.00 or permission of instructor
Units: 3-0-9
______
Modern software development techniques and algorithms for engineering computation. Hands-on investigation of computational and software techniques for simulating engineering systems, such as sensor networks, traffic networks, and discrete simulation of materials using atomistic and particle methods. Covers data structures and algorithms for modeling, analysis, and visualization in the setting of multi-core and distributed computing. Treatment of basic topics, such as queuing, sorting and search algorithms, and more advanced numerical techniques based on state machines and distributed agents. Foundation for in-depth exploration of image processing, optimization, finite element and particle methods, computational materials, discrete element methods, and network methods. Knowledge of an object-oriented language required.
J. R. Williams

2.092 Finite Element Analysis of Solids and Fluids I
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with2.093)
Prereq: 2.001; 2.003 or 2.03
Units: 3-0-9
URL: http://ocw.mit.edu/courses/mechanical-engineering/2-092-finite-element-analysis-of-solids-and-fluids-i-fall-2009/index.htm
______

2.093 Finite Element Analysis of Solids and Fluids I
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with2.092)
Prereq: 2.001; 2.003 or 2.03
Units: 3-0-9
URL: http://ocw.mit.edu/courses/mechanical-engineering/2-092-finite-element-analysis-of-solids-and-fluids-i-fall-2009/index.htm
______
Finite element methods for analysis of steady-state and transient problems in solid, structural, fluid mechanics, and heat transfer. Presents finite element methods and solution procedures for linear and nonlinear analyses using largely physical arguments. Demonstrates finite element analyses. Homework involves use of an existing general purpose finite element analysis program. Includes modeling of problems and interpretation of numerical results. Students taking graduate version complete additional assignments.
K. J. Bathe

2.096[J] Introduction to Numerical Simulation
______

Graduate (Fall)
(Same subject as6.336[J],16.910[J])
Prereq: 18.03 or 18.06
Units: 3-3-6
Lecture: MW1-2.30 (32-141)
______
Introduction to computational techniques for the simulation of a large variety of engineering and physical systems. Applications are drawn from aerospace, mechanical, electrical, chemical engineering, biology, and materials science. Topics include mathematical formulations (techniques for automatic assembly of mathematical problems from physics' principles); sparse, direct and iterative solution techniques for linear systems; Newton and Homotopy methods for nonlinear problems; discretization methods for ordinary, time-periodic and partial differential equations; accelerated methods for integral equations; techniques for automatic generation of compact dynamical system models and model order reduction.
L. Daniel, J. K. White
No required or recommended textbooks

2.097[J] Numerical Methods for Partial Differential Equations
______

Graduate (Fall)
(Same subject as6.339[J],16.920[J])
Prereq: 18.03 or 18.06
Units: 3-0-9
Lecture: MW9.30-11 (4-163)
______
Covers the fundamentals of modern numerical techniques for a wide range of linear and nonlinear elliptic, parabolic, and hyperbolic partial differential and integral equations. Topics include mathematical formulations; finite difference, finite volume, finite element, and boundary element discretization methods; and direct and iterative solution techniques. The methodologies described form the foundation for computational approaches to engineering systems involving heat transfer, solid mechanics, fluid dynamics, and electromagnetics. Computer assignments requiring programming.
Q. Wang, J. K. White
No textbook information available

2.099[J] Computational Mechanics of Materials
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as16.225[J])
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Formulation of numerical (finite element) methods for the analysis of the nonlinear continuum response of materials. The range of material behavior considered includes finite deformation elasticity and inelasticity. Numerical formulation and algorithms include variational formulation and variational constitutive updates; finite element discretization; constrained problems; time discretization and convergence analysis. Strong emphasis on the (parallel) computer implementation of algorithms in programming assignments. The application to real engineering applications and problems in engineering science are stressed throughout. Experience in either C++, C, or Fortran required.
R. Radovitzky

System Dynamics and Control

2.110[J] Information, Entropy, and Computation
______

Undergrad (Spring)
(Same subject as6.050[J])
Prereq: Physics I (GIR)
Units: 3-0-6
______
Explores the ultimate limits to communication and computation, with an emphasis on the physical nature of information and information processing. Topics include information and computation, digital signals, codes, and compression. Biological representations of information. Logic circuits, computer architectures, and algorithmic information. Noise, probability, and error correction. The concept of entropy applied to channel capacity and to the second law of thermodynamics. Reversible and irreversible operations and the physics of computation. Quantum computation.
P. Penfield, Jr., S. Lloyd

2.111[J] Quantum Computation
______

Graduate (Fall)
(Same subject as8.370[J],18.435[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (4-370) +final
______
Provides an introduction to the theory and practice of quantum computation. Topics covered: physics of information processing; quantum algorithms including the factoring algorithm and Grover's search algorithm; quantum error correction; quantum communication and cryptography. Knowledge of quantum mechanics helpful but not required.
I. Chuang, E. Farhi, S. Lloyd, P. Shor
Textbooks (Fall 2016)

2.12 Introduction to Robotics
______

Undergrad (Fall)
(Subject meets with2.120)
Prereq: 2.004, or 2.031 and 2.04A
Units: 3-2-7
Lecture: MW2.30-4 (3-270) Lab: R11-1 (5-007) or R1-3 (5-007) or R3-5 (5-007) or F9-11 (5-007) or F11-1 (5-007) or F2-4 (5-007)
______
Textbooks (Fall 2016)

2.120 Introduction to Robotics
______

Graduate (Fall)
(Subject meets with2.12)
Prereq: 2.004, or 2.031 and 2.04A, or permission of instructor
Units: 3-2-7
Lecture: MW2.30-4 (3-270) Lab: R11-1 (5-007) or R1-3 (5-007) or R3-5 (5-007) or F9-11 (5-007) or F11-1 (5-007) or F2-4 (5-007)
______
Presents the fundamentals of robot mechanisms, dynamics, and controls. Planar and spatial kinematics, differential motion, energy method for robot mechanics; mechanism design for manipulation and locomotion; multi-rigid-body dynamics; force and compliance control, balancing control, visual feedback, human-machine interface; actuators, sensors, wireless networking, and embedded software. Weekly laboratories include real-time control, vehicle navigation, arm and end-effector design, and balancing robot control. Group term project requires design and fabrication of robotic systems. Students taking graduate version complete additional assignments. Enrollment may be limited due to laboratory capacity.
H. Asada, J. J. Leonard
Textbooks (Fall 2016)

2.131 Advanced Instrumentation and Measurement
______

Graduate (Spring)
Prereq: Permission of Instructor
Units: 3-6-3
______
Provides training in advanced instrumentation and measurement techniques. Topics include system level design, fabrication and evaluation with emphasis on systems involving concepts and technology from mechanics, optics, electronics, chemistry and biology. Simulation, modeling and design software. Use of a wide range of instruments/techniques (e.g., scanning electron microscope, dynamic signal/system analyzer, impedance analyzer, laser interferometer) and fabrication/machining methods (e.g., laser micro-machining, stereo lithography, computer controlled turning and machining centers). Theory and practice of both linear and nonlinear system identification techniques. Lab sessions include instruction and group project work. No final exam.
I. W. Hunter

2.14 Analysis and Design of Feedback Control Systems
______

Undergrad (Spring)
(Subject meets with2.140)
Prereq: 2.004, 2.04A, or 2.04B
Units: 3-3-6
URL: http://me.mit.edu/2.14/
______

2.140 Analysis and Design of Feedback Control Systems
______

Graduate (Spring)
(Subject meets with2.14)
Prereq: 2.004, 2.04A, 2.04B, or permission of instructor
Units: 3-3-6
______
Develops the fundamentals of feedback control using linear transfer function system models. Analysis in time and frequency domains. Design in the s-plane (root locus) and in the frequency domain (loop shaping). Describing functions for stability of certain non-linear systems. Extension to state variable systems and multivariable control with observers. Discrete and digital hybrid systems and use of z-plane design. Extended design case studies and capstone group projects. Student taking graduate version complete additional assignments. Enrollment may be limited due to laboratory capacity.
D. Rowell, D. L. Trumper, K. Youcef-Toumi

2.141 Modeling and Simulation of Dynamic Systems
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 2.151
Units: 3-0-9
______
Modeling multidomain engineering systems at a level of detail suitable for design and control system implementation. Network representation, state-space models; multiport energy storage and dissipation, Legendre transforms; nonlinear mechanics, transformation theory, Lagrangian and Hamiltonian forms; Control-relevant properties. Application examples may include electro-mechanical transducers, mechanisms, electronics, fluid and thermal systems, compressible flow, chemical processes, diffusion, and wave transmission.
N. Hogan

2.151 Advanced System Dynamics and Control
______

Graduate (Fall)
Prereq: 2.004, 18.06; or 2.087, 2.04A
Units: 4-0-8
Lecture: TR1-2.30 (3-370) Recitation: W4 (37-212)
______
Analytical descriptions of state-determined dynamic physical systems; time and frequency domain representations; system characteristics - controllability, observability, stability; linear and nonlinear system responses. Modification of system characteristics using feedback. State observers, Kalman filters. Modeling/performance trade-offs in control system design. Basic optimization tools. Positive systems. Emphasizes applications to physical systems.
J.-J. E. Slotine, K. Youcef-Toumi, N. Hogan
Textbooks (Fall 2016)

2.152[J] Nonlinear Control
______

Graduate (Spring)
(Same subject as9.110[J])
Prereq: 2.151, 6.241, 16.31, or permission of instructor
Units: 3-0-9
______
Introduction to nonlinear control and estimation in physical and biological systems. Nonlinear stability theory, Lyapunov analysis, Barbalat's lemma. Feedback linearization, differential flatness, internal dynamics. Sliding surfaces. Adaptive nonlinear control and estimation. Multiresolution bases, nonlinear system identification. Contraction analysis, differential stability theory. Nonlinear observers. Asynchronous distributed computation and learning. Concurrent synchronization, polyrhythms. Monotone nonlinear systems. Emphasizws application to physical systems (robots, aircraft, spacecraft, underwater vehicles, reaction-diffusion processes, machine vision, oscillators, internet), machine learning, computational neuroscience, and systems biology. Includes term projects.
J.-J. E. Slotine

2.153 Adaptive Control
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 2.151
Units: 3-0-9
______
Introduces the foundation of adaptive control in continuous-time and discrete-time systems. Adaptive control is the ability to self-correct a controller in the presence of parametric uncertainties using online information is its main and most compelling feature. Examples drawn from aerospace, propulsion, automotive, and energy systems will be used to elucidate the underlying concepts.
A. Annaswamy

2.154 Maneuvering and Control of Surface and Underwater Vehicles
______

Graduate (Fall)
Prereq: 2.22
Units: 3-0-9
Lecture: TR9.30-11 (1-132)
______
Maneuvering motions of surface and underwater vehicles. Derivation of equations of motion, hydrodynamic coefficients. Memory effects. Linear and nonlinear forms of the equations of motion. Control surfaces modeling and design. Engine, propulsor, and transmission systems modeling and simulation during maneuvering. Stability of motion. Principles of multivariable automatic control. Optimal control, Kalman filtering, loop transfer recovery. Term project: applications chosen from autopilots for surface vehicles; towing in open seas; remotely operated vehicles.
M. S. Triantafyllou
No required or recommended textbooks

2.160 Identification, Estimation, and Learning
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 2.151
Units: 3-0-9
______
Provides a broad theoretical basis for system identification, estimation, and learning. Least squares estimation and its convergence properties, Kalman filter and extended Kalman filter, noise dynamics and system representation, function approximation theory, neural nets, radial basis functions, wavelets, Volterra expansions, informative data sets, persistent excitation, asymptotic variance, central limit theorems, model structure selection, system order estimate, maximum likelihood, unbiased estimates, Cramer-Rao lower bound, Kullback-Leibler information distance, Akaike's information criterion, experiment design, and model validation.
H. Asada, J.-J. E. Slotine

2.165[J] Robotics
______

Graduate (Spring)
(Same subject as9.175[J])
Prereq: 2.151 or permission of instructor
Units: 3-0-9
______
Dynamic analysis, design, and control of robots. Forward and inverse kinematics and dynamics of multi-input, multi-output rigid body systems. Computed torque control. Adaptive control. System identification. Force feedback, adaptive visual servoing. Task planning, teleoperation. Elements of biological planning and control. Motor primitives, entrainment, locomotion, active sensing, binding models. Term projects.
J.-J. E. Slotine, H. Asada

2.166 Autonomous Vehicles
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.041B or permission of instructor
Units: 3-1-8
______
Theory and application of probabilistic techniques for autonomous mobile robotics. Topics include probabilistic state estimation and decision making for mobile robots; stochastic representations of the environment; dynamic models and sensor models for mobile robots; algorithms for mapping and localization; planning and control in the presence of uncertainty; cooperative operation of multiple mobile robots; mobile sensor networks; application to autonomous marine (underwater and floating), ground, and air vehicles.
J. J. Leonard

2.167 Hands-On Marine Robotics
______

Not offered academic year 2016-2017Undergrad (Fall) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
______
Direct experience in developing marine robotic systems, from conceptualization and design through manufacture and testing. The class consists of a weekly seminar with readings and discussions, and significant outside work on student projects, culminating in a written report each term. Seminar topics include tools for unmanned marine work and their history, analysis of mission requirements, conceptual design and modeling of systems, experiments and proofs of concept, and project pacing and time management. A total of up to 12 hours credit may be taken over one or two terms; seminar topics repeat yearly.
F. S. Hover

2.171 Analysis and Design of Digital Control Systems
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 2.14, 2.151, or permission of instructor
Units: 3-3-6
URL: http://web.mit.edu/2.171/www/
Subject Cancelled Subject Cancelled
______
A comprehensive introduction to digital control system design, reinforced with hands-on laboratory experiences. Major topics include discrete-time system theory and analytical tools; design of digital control systems via approximation from continuous time; direct discrete-time design; loop-shaping design for performance and robustness; state-space design; observers and state-feedback; quantization and other nonlinear effects; implementation issues. Laboratory experiences and design projects connect theory with practice.
D. L. Trumper

2.18[J] Biomolecular Feedback Systems
______

Graduate (Spring)
(Same subject as6.557[J])
(Subject meets with2.180[J],6.027[J])
Prereq: 18.03, Biology (GIR), or permission of instructor
Units: 3-0-9
______

2.180[J] Biomolecular Feedback Systems
______

Undergrad (Spring)
(Same subject as6.027[J])
(Subject meets with2.18[J],6.557[J])
Prereq: 18.03, Biology (GIR), or permission of instructor
Units: 3-0-9
______
Comprehensive introduction to dynamics and control of biomolecular systems with emphasis on design/analysis techniques from control theory. Provides a review of biology concepts, regulation mechanisms, and models. Covers basic enabling technologies, engineering principles for designing biological functions, modular design techniques, and design limitations. Students taking graduate version complete additional assignments.
D. Del Vecchio

2.183[J] Biomechanics and Neural Control of Movement
______

Graduate (Spring)
(Same subject as9.34[J])
(Subject meets with2.184)
Prereq: 2.004, 2.04A, or permission of instructor
Units: 3-0-9
______

2.184 Biomechanics and Neural Control of Movement
______

Undergrad (Spring)
(Subject meets with2.183[J],9.34[J])
Prereq: 2.004, 2.04A, or permission of instructor
Units: 3-0-9
______
Quantitative knowledge of human movement behavior is important in a growing number of engineering applications (medical and rehabilitation technology, athletic and military equipment, human-computer interaction, vehicle performance, etc.). Presents a quantitative, model-based description of how biomechanical and neural factors interact in human sensory-motor behavior, focusing mainly on the upper limbs. Students survey recent literature on how motor behavior is controlled, comparing biological and robotic approaches to similar tasks. Topics may include a review of relevant neural, muscular and skeletal physiology, neural feedback and "equilibrium-point" theories, co-contraction strategies, impedance control, kinematic redundancy, optimization, intermittency, contact tasks and tool use. Students taking the graduate version will complete additional assignments.
N. Hogan


left arrow|2.000-2.199|2.20-2.7999|2.80-2.999 plus Thesis, UROP, UPOP|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 2: Mechanical Engineering
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Course 2: Mechanical Engineering
Fall 2016


Fluid Mechanics and Combustion

2.20 Marine Hydrodynamics
______

Graduate (Fall)
Prereq: 1.060B, 2.006, 2.06, or 2.016
Units: 4-1-7
Lecture: TR1-2.30 (1-246) Recitation: W11 (1-379) or W1 (1-371) or W4 (1-132) +final
______
The fundamentals of fluid mechanics are developed in the context of naval architecture and ocean science and engineering. Transport theorem and conservation principles. Navier-Stokes' equation. Dimensional analysis. Ideal and potential flows. Vorticity and Kelvin's theorem. Hydrodynamic forces in potential flow, D'Alembert's paradox, added-mass, slender-body theory. Viscous-fluid flow, laminar and turbulent boundary layers. Model testing, scaling laws. Application of potential theory to surface waves, energy transport, wave/body forces. Linearized theory of lifting surfaces. Experimental project in the towing tank or propeller tunnel.
D. K. P. Yue
Textbooks (Fall 2016)

2.22 Design Principles for Ocean Vehicles
______

Graduate (Spring)
Prereq: 2.20
Units: 3-3-6
______
Design tools for analysis of linear systems and random processes related to ocean vehicles; description of ocean environment including random waves, ocean wave spectra and their selection; short and long term wave statistics; and ocean currents. Advanced hydrodynamics for design of ocean vehicles and offshore structures including wave forces on towed and moored structures; inertia vs. drag dominated flows; vortex induced vibrations of offshore structures; ship seakeeping and sensitivity of seakeeping performance. Design exercises in application of principles. Several laboratory exercises emphasizing modern measurement techniques, model testing, and flow diagnostic tools.
M. S. Triantafyllou

2.23 Hydrofoils and Propellers
______

Not offered academic year 2017-2018Graduate (Fall); first half of term
Prereq: 2.20, 18.085
Units: 2-0-4
Ends Oct 21. Lecture: MW3.30-5 (1-134) Recitation: T4 (1-132)
______
Reviews the theory and design of hydrofoil sections; lifting and thickness problems for sub-cavitating sections and unsteady flow problems. Covers lifting line and lifting surface theory with applications to hydrofoil craft, rudder, control surface, propeller and wind turbine rotor design. Topics include propeller lifting line and lifting surface theory; wake adapted propellers, steady and unsteady propeller thrust and torque; waterjets; performance analysis and design of wind turbine rotors. Presents numerical principles of vortex lattice and lifting surface panel methods. Projects illustrate the development of theoretical and computational methods for lifting, propulsion and wind turbine applications.
P. D. Sclavounos
No required or recommended textbooks

2.24[J] Ocean Wave Interaction with Ships and Offshore Energy Systems
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as1.692[J])
Prereq: 2.20, 18.085
Units: 4-0-8
______
Surface wave theory, conservation laws and boundary conditions, properties of regular surface waves and random ocean waves. Linearized theory of floating body dynamics, kinematic and dynamic free surface conditions, body boundary conditions. Simple harmonic motions. Diffraction and radiation problems, added mass and damping matrices. General reciprocity identities on diffraction and radiation. Ship wave resistance theory, Kelvin wake physics, ship seakeeping in regular and random waves. Discusses point wave energy absorbers, beam sea and head-sea devises, oscillating water column device and Well's turbine. Discusses offshore floating energy systems and their interaction with ambient waves, current and wind, including oil and gas platforms, liquefied natural gas (LNG) vessels and floating wind turbines. Homework drawn from real-world applications.
P. D. Sclavounos

2.25 Fluid Mechanics
______

Graduate (Fall)
Prereq: 2.006 or 2.06;Coreq: 18.075 or 18.085
Units: 4-0-8
URL: http://web.mit.edu/2.25/www/
Lecture: TR11-12.30 (3-270) Recitation: W11 (1-135) or R3 (1-242) or R4 (1-242) +final
______
Survey of principal concepts and methods of fluid dynamics. Mass conservation, momentum, and energy equations for continua. Navier-Stokes equation for viscous flows. Similarity and dimensional analysis. Lubrication theory. Boundary layers and separation. Circulation and vorticity theorems. Potential flow. Introduction to turbulence. Lift and drag. Surface tension and surface tension driven flows.
A. F. Ghoniem, A. E. Hosoi, G. H. McKinley, A. T. Patera
Textbooks (Fall 2016)

2.250[J] Fluid Dynamics and Disease
(New)
______

Graduate (Spring)
(Same subject as1.631[J],HST.537[J])
Prereq: None
Units: 3-0-9
______
Reviews theoretical notions in mathematical epidemiology and open problems in understanding and modeling disease onset and spread. Bridges the disease modeling efforts at the large-scale population-level and those at the micro-scale pathogen-level via the use of fluid dynamics. Covers topics such as interfacial flows, fluid fragmentation, multiphase flows, turbulent flows, and fluid-structure interaction. Intended for students with a strong quantitative background interested in learning about applications in health and epidemiology and for students with an epidemiology and health background interested in learning about fluid dynamics approaches relevant to disease transmission. In the spirit of the OneHealth Initiative, covers advanced topics on the health of human, animal, and plant populations.
L. Bourouiba

2.26[J] Advanced Fluid Dynamics
______

Graduate (Spring)
(Same subject as1.63[J])
Prereq: 18.085; 2.25 or permission of instructor.
Units: 4-0-8
URL: http://web.mit.edu/2.26/www/index.html
______
Fundamentals of fluid dynamics intrinsic to natural physical phenomena and/or engineering processes. Discusses a range of topics and advanced problem-solving techniques. Sample topics include brief review of basic laws of fluid motion, scaling and approximations, creeping flows, boundary layers in high-speed flows, steady and transient, similarity method of solution, buoyancy-driven convection in porous media, dispersion in steady or oscillatory flows, physics and mathematics of linearized instability, effects of shear and stratification. In alternate years, two of the following modules will be offered: I: Geophysical Fluid Dynamics of Coastal Waters, II: Capillary Phenomena, III: Non-Newtonian Fluids, IV: Flagellar Swimming.
T. R. Akylas, G. H. McKinley, R. Stocker

2.28 Fundamentals and Applications of Combustion
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 2.006, or 2.051 and 2.06
Units: 3-0-9
______
Fundamentals and modeling of reacting gas dynamics and combustion using analytical and numerical methods. Conservation equations of reacting flows. Multi-species transport, chemical thermodynamics and chemical kinetics. Non-equilibrium flow. Detonation and reacting boundary layers. Ignition, flammability, and extinction. Premixed and diffusion flames. Combustion instabilities. Supersonic combustion. Turbulent combustion. Liquid and solid burning. Fire, safety, and environmental impact. Applications to power and propulsion.
A. F. Ghoniem

2.29 Numerical Fluid Mechanics
______

Graduate (Spring)
Prereq: 2.006, 2.06, 2.016, 2.20, or 2.25; 18.075
Units: 4-0-8
______
Introduction to numerical methods and MATLAB: errors, condition numbers and roots of equations. Navier-Stokes. Direct and iterative methods for linear systems. Finite differences for elliptic, parabolic and hyperbolic equations. Fourier decomposition, error analysis and stability. High-order and compact finite-differences. Finite volume methods. Time marching methods. Navier-Stokes solvers. Grid generation. Finite volumes on complex geometries. Finite element methods. Spectral methods. Boundary element and panel methods. Turbulent flows. Boundary layers. Lagrangian Coherent Structures. Includes a final research project.
P. F. J. Lermusiaux

2.341[J] Macromolecular Hydrodynamics
______

Graduate (Spring)
(Same subject as10.531[J])
Prereq: 2.25, 10.301, or permission of instructor
Units: 3-0-6
______
Physical phenomena in polymeric liquids undergoing deformation and flow. Kinematics and material functions for complex fluids; techniques of viscometry, rheometry; and linear viscoelastic measurements for polymeric fluids. Generalized Newtonian fluids. Continuum mechnanics, frame invariance, and convected derivatives for finite strain viscoelasticity. Differential and integral constitutive equations for viscoelastic fluids. Analytical solutions to isothermal and non-isothermal flow problems; the roles of non-Newtonian viscosity, linear viscoelasticity, normal stresses, elastic recoil, stress relaxation in processing flows. Introduction to molecular theories for dynamics of polymeric fluids. (Extensive class project and presentation required instead of a final exam).
R. C. Armstrong, G. H. McKinley

MEMS and Nanotechnology

2.37 Fundamentals of Nanoengineering
______

Graduate (Spring)
(Subject meets with2.370)
Prereq: Permission of instructor
Units: 3-0-9
______

2.370 Fundamentals of Nanoengineering
______

Undergrad (Spring)
(Subject meets with2.37)
Prereq: 2.001; Chemistry (GIR)
Units: 3-0-9
______
Presents the fundamentals of molecular modeling in engineering in the context of nanoscale mechanical engineering applications. Statistical mechanics and its connection to engineering thermodynamics. Molecular origin and limitations of macroscopic descriptions and constitutive relations for equilibrium and non-equilibrium behavior. Introduction to molecular simulation, solid-state physics and electrokinetic phenomena. Discusses molecular approaches to modern nanoscale engineering problems. Graduate students are required to complete additional assignments with stronger analytical content.
N. G. Hadjiconstantinou

2.372[J] Design and Fabrication of Microelectromechanical Systems
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as6.777[J])
(Subject meets with2.374[J],6.717[J])
Prereq: 6.003 or 2.003, Physics II (GIR); or permission of instructor
Units: 3-0-9
______

2.374[J] Design and Fabrication of Microelectromechanical Systems
______

Not offered academic year 2016-2017Undergrad (Spring)
(Same subject as6.717[J])
(Subject meets with2.372[J],6.777[J])
Prereq: 6.003 or 2.003, Physics II (GIR); or permission of instructor
Units: 3-0-9
______
Provides an introduction to microsystem design. Covers material properties, microfabrication technologies, structural behavior, sensing methods, electromechanical actuation, thermal actuation and control, multi-domain modeling, noise, and microsystem packaging. Applies microsystem modeling, and manufacturing principles to the design and analysis a variety of microscale sensors and actuators (e.g., optical MEMS, bioMEMS, and inertial sensors). Emphasizes modeling and simulation in the design process. Students taking the graduate version complete additional assignments.
Staff

2.391[J] Nanostructure Fabrication
______

Graduate (Spring)
(Same subject as6.781[J])
Prereq: 6.152, 6.161, or 2.710; or permission of instructor
Units: 4-0-8
______
Describes current techniques used to analyze and fabricate nanometer-length-scale structures and devices. Emphasizes imaging and patterning of nanostructures, including fundamentals of optical, electron (scanning, transmission, and tunneling), and atomic-force microscopy; optical, electron, ion, and nanoimprint lithography, templated self-assembly, and resist technology. Surveys substrate characterization and preparation, facilities, and metrology requirements for nanolithography. Addresses nanodevice processing methods, such as liquid and plasma etching, lift-off, electroplating, and ion-implant. Discusses applications in nanoelectronics, nanomaterials, and nanophotonics.
K. K. Berggren

Thermodynamics

2.42 General Thermodynamics
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR12.30-2 (3-333) +final
______
General foundations of thermodynamics from an entropy point of view, entropy generation and transfer in complex systems. Definitions of work, energy, stable equilibrium, available energy, entropy, thermodynamic potential, and interactions other than work (nonwork, heat, mass transfer). Applications to properties of materials, bulk flow, energy conversion, chemical equilibrium, combustion, and industrial manufacturing.
J. Brisson
No required or recommended textbooks

Heat and Mass Transfer

2.500 Desalination and Water Purification
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: 1.020, 2.006, 10.302, or 2.051 and 2.06, or permission of instructor
Units: 3-0-9
______
Introduces the fundamental science and technology of desalinating water to overcome water scarcity and ensure sustainable water supplies. Covers basic water chemistry, flash evaporation, reverse osmosis and membrane engineering, electrodialysis, nanofiltration, solar desalination, energy efficiency of desalination systems, fouling and scaling, environmental impacts, and economics of desalination systems. Open to upper-class undergraduates.
J. H. Lienhard, M. Balaban

2.51 Intermediate Heat and Mass Transfer
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 2.006, or 2.051 and 2.06, or permission of instructor
Units: 3-0-9
______
Analysis, modeling, and design of heat and mass transfer processes with application to common technologies. Unsteady heat conduction in one or more dimensions, steady conduction in multidimensional configurations, numerical simulation; forced convection in laminar and turbulent flows; natural convection in internal and external configurations; phase change heat transfer; thermal radiation, black bodies, grey radiation networks, spectral and solar radiation; mass transfer at low rates, evaporation.
J. H. Lienhard, E. N. Wang

2.52[J] Modeling and Approximation of Thermal Processes
______

Graduate (Fall)
(Same subject as4.424[J])
Prereq: 2.51
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4424
Lecture: MW12.30-2 (5-217)
______
Provides instruction on how to model thermal transport processes in typical engineering systems such as those found in manufacturing, machinery, and energy technologies. Successive modules cover basic modeling tactics for particular modes of transport, including steady and unsteady heat conduction, convection, multiphase flow processes, and thermal radiation. Includes a creative design project executed by the students.
L. R. Glicksman
Textbooks (Fall 2016)

2.55 Advanced Heat and Mass Transfer
______

Graduate (Spring)
Prereq: 2.51
Units: 4-0-8
URL: http://web.mit.edu/2.55/www/
______
Advanced treatment of fundamental aspects of heat and mass transport. Covers topics such as diffusion kinetics, conservation laws, laminar and turbulent convection, mass transfer including phase change or heterogeneous reactions, and basic thermal radiation. Problems and examples include theory and applications drawn from a spectrum of engineering design and manufacturing problems.
J. H. Lienhard

2.57 Nano-to-Macro Transport Processes
______

Graduate (Spring)
Not offered regularly; consult department
(Subject meets with2.570)
Prereq: 2.005, 2.051, or permission of instructor
Units: 3-0-9
______

2.570 Nano-to-Macro Transport Processes
______

Undergrad (Spring)
Not offered regularly; consult department
(Subject meets with2.57)
Prereq: 2.005, 2.051, or permission of instructor
Units: 3-0-9
______
Parallel treatments of photons, electrons, phonons, and molecules as energy carriers; aiming at a fundamental understanding of descriptive tools for energy and heat transport processes, from nanoscale to macroscale. Topics include energy levels; statistical behavior and internal energy; energy transport in the forms of waves and particles; scattering and heat generation processes; Boltzmann equation and derivation of classical laws; and deviation from classical laws at nanoscale and their appropriate descriptions. Applications in nanotechnology and microtechnology. Students taking the graduate version complete additional assignments.
G. Chen

2.59[J] Thermal Hydraulics in Power Technology
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as10.536[J],22.313[J])
Prereq: 2.006, 10.302, 22.312, or permission of instructor
Units: 3-2-7
______
Emphasis on thermo-fluid dynamic phenomena and analysis methods for conventional and nuclear power stations. Kinematics and dynamics of two-phase flows. Steam separation. Boiling, instabilities, and critical conditions. Single-channel transient analysis. Multiple channels connected at plena. Loop analysis including single and two-phase natural circulation. Subchannel analysis.
E. Baglietto

Energy and Power Systems

2.60[J] Fundamentals of Advanced Energy Conversion
______

Undergrad (Spring)
(Same subject as10.390[J])
(Subject meets with2.62[J],10.392[J],22.40[J])
Prereq: 2.006, or 2.051 and 2.06, or permission of instructor
Units: 4-0-8
______
Fundamentals of thermodynamics, chemistry, and transport applied to energy systems. Analysis of energy conversion and storage in thermal, mechanical, chemical, and electrochemical processes in power and transportation systems, with emphasis on efficiency, performance, and environmental impact. Applications to fuel reforming and alternative fuels, hydrogen, fuel cells and batteries, combustion, catalysis, combined and hybrid power cycles using fossil, nuclear and renewable resources. CO2 separation and capture. Biomass energy. Students taking graduate version complete additional assignments.
A. F. Ghoniem, W. Green

2.61 Internal Combustion Engines
______

Graduate (Spring)
Prereq: 2.006
Units: 3-1-8
URL: http://web.mit.edu/2.61/www/index.html
______
Fundamentals of how the design and operation of internal combustion engines affect their performance, efficiency, fuel requirements, and environmental impact. Study of fluid flow, thermodynamics, combustion, heat transfer and friction phenomena, and fuel properties, relevant to engine power, efficiency, and emissions. Examination of design features and operating characteristics of different types of internal combustion engines: spark-ignition, diesel, stratified-charge, and mixed-cycle engines. Engine Laboratory project. For graduate and senior undergraduate students.
W. K. Cheng

2.611 Marine Power and Propulsion
______

Graduate (Fall)
(Subject meets with2.612)
Prereq: 2.005
Units: 4-0-8
Lecture: TR9.30-11 (5-217) Recitation: F10 (5-217)
______
Textbooks (Fall 2016)

2.612 Marine Power and Propulsion
______

Undergrad (Fall)
(Subject meets with2.611)
Prereq: 2.005
Units: 4-0-8
Lecture: TR9.30-11 (5-217) Recitation: F10 (5-217)
______
Selection and evaluation of commercial and naval ship power and propulsion systems. Analysis of propulsors, prime mover thermodynamic cycles, propeller-engine matching. Propeller selection, waterjet analysis, review of alternative propulsors; thermodynamic analyses of Rankine, Brayton, Diesel, and Combined cycles, reduction gears and integrated electric drive. Battery operated vehicles, fuel cells. Term project requires analysis of alternatives in propulsion plant design for given physical, performance, and economic constraints. Graduate students complete different assignments and exams.
J. Harbour, M. S. Triantafyllou, R. S. McCord
Textbooks (Fall 2016)

2.62[J] Fundamentals of Advanced Energy Conversion
______

Graduate (Spring)
(Same subject as10.392[J],22.40[J])
(Subject meets with2.60[J],10.390[J])
Prereq: 2.006, or 2.051 and 2.06, or permission of instructor
Units: 4-0-8
______
Fundamentals of thermodynamics, chemistry, and transport applied to energy systems. Analysis of energy conversion and storage in thermal, mechanical, chemical, and electrochemical processes in power and transportation systems, with emphasis on efficiency, performance and environmental impact. Applications to fuel reforming and alternative fuels, hydrogen, fuel cells and batteries, combustion, catalysis, combined and hybrid power cycles using fossil, nuclear and renewable resources. CO2 separation and capture. Biomass energy. Meets with 2.60 when offered concurrently; students taking the graduate version complete additional assignments.
A. F. Ghoniem, W. Green

2.625[J] Electrochemical Energy Conversion and Storage: Fundamentals, Materials and Applications
______

Graduate (Fall)
(Same subject as10.625[J])
Prereq: 2.005, 3.046, 3.53, 10.40, or 2.051 and 2.06, or permission of instructor
Units: 4-0-8
Lecture: TR2.30-4 (3-333) Recitation: W4 (1-150)
______
Fundamental concepts, tools, and applications in electrochemical science and engineering. Introduces thermodynamics, kinetics and transport of electrochemical reactions. Describes how materials structure and properties affect electrochemical behavior of particular applications, for instance in lithium rechargeable batteries, electrochemical capacitors, fuel cells, photo electrochemical cells, and electrolytic cells. Discusses state-of-the-art electrochemical energy technologies for portable electronic devices, hybrid and plug-in vehicles, electrical vehicles. Theoretical and experimental exploration of electrochemical measurement techniques in cell testing, and in bulk and interfacial transport measurements (electronic and ionic resistivity and charge transfer cross the electrode-electrolyte interface).
Y. Shao-Horn
No textbook information available

2.626 Fundamentals of Photovoltaics
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with2.627)
Prereq: Permission of instructor
Units: 4-0-8
______

2.627 Fundamentals of Photovoltaics
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with2.626)
Prereq: Permission of instructor
Units: 4-0-8
______
Fundamentals of photoelectric conversion: charge excitation, conduction, separation, and collection. Studies commercial and emerging photovoltaic technologies. Cross-cutting themes include conversion efficiencies, loss mechanisms, characterization, manufacturing, systems, reliability, life-cycle analysis, and risk analysis. Photovoltaic technology evolution in the context of markets, policies, society, and environment. Graduate students complete additional work.
T. Buonassisi

2.65[J] Sustainable Energy
______

Graduate (Fall)
(Same subject as1.818[J],10.391[J],11.371[J],22.811[J])
(Subject meets with2.650[J],10.291[J],22.081[J])
Prereq: Permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/10.391J/www/
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various energy technologies in each fuel cycle stage for fossil (oil, gas, synthetic), nuclear (fission and fusion) and renewable (solar, biomass, wind, hydro, and geothermal) energy types, along with storage, transmission, and conservation issues. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments.
M. W. Golay
Textbooks (Fall 2016)

2.650[J] Introduction to Sustainable Energy
______

Undergrad (Fall)
(Same subject as10.291[J],22.081[J])
(Subject meets with1.818[J],2.65[J],10.391[J],11.371[J],22.811[J])
Prereq: Permission of instructor
Units: 3-1-8
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various renewable and conventional energy production technologies, energy end-use practices and alternatives, and consumption practices in different countries. Investigates their attributes within a quantitative analytical framework for evaluation of energy technology system proposals. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments. Limited to juniors and seniors.
M. W. Golay
Textbooks (Fall 2016)

2.651[J] D-Lab: Energy
______

Undergrad (Spring)
(Same subject asEC.711[J])
(Subject meets withEC.791)
Prereq: None
Units: 3-3-6
______
Provides a project-based approach that engages students in understanding and addressing the applications of alternative energy technology in developing countries. Focuses on compact, robust, low-cost systems for generating electrical power. Includes projects such as micro-hydro, solar, or wind turbine generators along with theoretical analysis, design, prototype construction, evaluation and implementation. Students will have the opportunity for an optional spring break site visit to identify and implement projects. Students taking graduate version complete additional assignments. Enrollment limited by lottery; must attend first class session.
S. L. Hsu

2.66[J] Fundamentals of Energy in Buildings
______

Not offered academic year 2016-2017Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject as1.044[J],4.42[J])
Prereq: Physics I (GIR), Calculus II (GIR)
Units: 3-2-7
______
Design-based introduction to energy and thermo-sciences, with applications to sustainable, energy-efficient architecture and building technology. Covers introductory thermodynamics, air/water/vapor mixtures, and heat transfer. Studies leading order factors in building energy use. Includes several building design projects in which students creatively employ energy fundamentals and building energy use.
L. R. Glicksman

Experimental Engineering

2.670 Mechanical Engineering Tools
______

Undergrad (IAP)
Prereq: None
Units: 0-1-2
______
Introduces the fundamentals of machine tools use and fabrication techniques. Students work with a variety of machine tools including the bandsaw, milling machine, and lathe. Mechanical Engineering students are advised to take this subject in the first IAP after declaring their major. Enrollment may be limited due to laboratory capacity. Preference to Course 2 majors and minors.
M. Culpepper

2.671 Measurement and Instrumentation
______

Undergrad (Fall, Spring) Institute Lab
Prereq: 2.001; 2.003 or 2.03; 2.086; Physics II (GIR)
Units: 3-3-6
URL: http://web.mit.edu/2.671/www/
Pre-reg required. Lecture: TR12.30-2 (3-270) Lab: M2-5 (3-038) or T9-12 (3-038) or T2-5 (3-038) or R9-12 (3-038) or R2-5 (3-038) or F9-12 (3-038) or F1.30-4.30 (3-038)
______
Experimental techniques for observation and measurement of physical variables such as force, strain, temperature, flow rate, and acceleration. Emphasizes principles of transduction, measurement circuitry, MEMS sensors, Fourier transforms, linear and nonlinear function fitting, uncertainty analysis, probability density functions and statistics, system identification, electrical impedance analysis and transfer functions, computer-aided experimentation, and technical reporting. Typical laboratory experiments involve oscilloscopes, electronic circuits including operational amplifiers, thermocouples, strain gauges, digital recorders, lasers, etc. Basic material and lab objectives are developed in lectures. Instruction and practice in oral and written communication provided. Enrollment limited.
I. W. Hunter, J. J. Leonard
No required or recommended textbooks

2.673[J] Instrumentation and Measurement for Biological Systems
______

Undergrad (Fall, Spring)
(Same subject as20.309[J])
(Subject meets with20.409)
Prereq: Biology (GIR), Physics II (GIR), 6.0002, 18.03; or permission of instructor
Units: 3-6-3
Lecture: TR12 (32-155) Recitation: F12 (56-114)
______
Sensing and measurement aimed at quantitative molecular/cell/tissue analysis in terms of genetic, biochemical, and biophysical properties. Methods include light and fluorescence microscopies, and electro-mechanical probes (atomic force microscopy, optical traps, MEMS devices). Application of statistics, probability, signal and noise analysis, and Fourier techniques to experimental data. Enrollment limited; preference to Course 20 undergraduates.
Fall:P. Blainey, S. Manalis, E. Frank, S. Wasserman, J. Bagnall
Spring:E. Boyden, P. So, S. Wasserman, J. Bagnall, E. Frank
No textbook information available

2.674 Micro/Nano Engineering Laboratory
______

Undergrad (Fall, Spring)
Prereq: 2.001; 2.003 or 2.03; 2.671;Coreq: 2.005, or 2.051 and 2.06; or permission of instructor
Units: 1-3-2
Lecture: T11 (35-225) Lab: R9-12 (5-026) or R1-4 (5-026) or F9-12 (5-026) or F1-4 (5-026) +final
______
Concepts, ideas, and enabling tools of nanoengineering taught through lab modules and imaging tools, which include microfluidics, microthermal systems, MEMS, nanomaterials, SEM, TEM, and AFM. Provides practical knowledge and experience via building, observing and manipulating micro- and nanoscale structures. Teaches students how to apply engineering knowledge to practical fluid, thermal, and dynamic systems at small scales. Meets with 2.675 in the fall term. Enrollment limited; preference to Course 2 majors and minors.
S. G. Kim, G. Chen, E. Wang, R. Karnik
No required or recommended textbooks

2.675 Micro/Nano Engineering Laboratory
______

Graduate (Fall)
Prereq: 2.25; 2.372 or permission of instructor
Units: 2-3-7
Lecture: T11 (35-225) Lab: R9-12 (5-026) or R1-4 (5-026) or F9-12 (5-026) or F1-4 (5-026) Recitation: T12 (37-212) +final
______
Concepts, ideas, and enabling tools of nanoengineering taught through lab modules and imaging tools, which include microfluidics, microthermal systems, MEMS, nanomaterials, SEM, TEM, and AFM. Provides practical knowledge and experience via building, observing and manipulating micro- and nanoscale structures. Teaches students how to apply engineering knowledge to practical fluid, thermal, and dynamic systems at small scales. Meets with 2.674 in the fall term. Enrollment limited.
S. G. Kim, G. Chen, E. Wang, R. Karnik
No required or recommended textbooks

2.678 Electronics for Mechanical Systems
______

Undergrad (Fall, Spring)
Prereq: Physics II (GIR)
Units: 2-2-2
Lecture: MW11 (3-270) Lab: W12.30-2.30 (3-062) or W3-5 (3-062) or R12.30-2.30 (3-062) or R3-5 (3-062) or F11-1 (3-062) or F2-4 (3-062)
______
Practical introduction to the fundamentals of electronics in the context of electro-mechanical systems, with emphasis on experimentation and project work in basic electronics. Laboratory exercises include the design and construction of simple electronic devices, such as power supplies, amplifiers, op-amp circuits, switched mode dc-dc converters, and dc motor drivers. Surveys embedded microcontrollers as system elements. Laboratory sessions stress the understanding of electronic circuits at the component level, but also point out the modern approach of system integration using commercial modules and specialized integrated circuits. Enrollment may be limited due to laboratory capacity; preference to Course 2 majors and minors.
D. Rowell
No required or recommended textbooks

Oceanographic Engineering and Acoustics

2.680 Unmanned Marine Vehicle Autonomy, Sensing, and Communication
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 2-6-4
______
Focuses on software and algorithms for autonomous decision making (autonomy) by underwater vehicles operating in ocean environments. Discusses how autonomous marine vehicles (UMVs) adapt to the environment for improved sensing performance. Covers sensors for acoustic, biological and chemical sensing and their integration with the autonomy system for environmentally adaptive undersea mapping and observation. Introduces students to the underwater acoustic communication environment and various options for undersea navigation, highlighting their relevance to the operation of collaborative undersea networks for environmental sensing. Labs involve the use of the MOOP-IvP autonomy software for the development of integrated sensing, modeling and control solutions. Solutions modeled in simulation environments and include field tests with small autonomous surface and underwater vehicles operated on the Charles River. Limited enrollment.
H. Schmidt, J.J. Leonard, M. Benjamin

2.681 Environmental Ocean Acoustics
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 2.066, 18.075 or permission of instructor
Units: 3-0-9
______
Fundamentals of underwater sound, and its application to mapping and surveillance in an ocean environment. Wave equations for fluid and elastic media. Reflection and transmission of sound at plane interfaces. Wave theory representation of acoustic source radiation and propagation in shallow and deep ocean waveguides. Interaction of underwater sound with elastic waves in the seabed and an Arctic ice cover, including effects of porosity and anisotropy. Numerical modeling of the propagation of underwater sound, including spectral methods, normal mode theory, and the parabolic equation method, for laterally homogeneous and inhomogeneous environments. Doppler effects. Effects of oceanographic variability and fluctuation - spatial and temporal coherence. Generation and propagation of ocean ambient noise. Modeling and simulation of signals and noise in traditional sonar systems, as well as modern, distributed, autonomous acoustic surveillance systems.
H. Schmidt

2.682 Acoustical Oceanography
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: 2.681
Units: 3-0-9
______
Provides brief overview of what important current research topics are in oceanography (physical, geological, and biological) and how acoustics can be used as a tool to address them. Three typical examples are climate, bottom geology, and marine mammal behavior. Addresses the acoustic inverse problem, reviewing inverse methods (linear and nonlinear) and the combination of acoustical methods with other measurements as an integrated system. Concentrates on specific case studies, taken from current research journals.
J. F. Lynch, Woods Hole Staff

2.683 Marine Bioacoustics and Geoacoustics
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: 2.681
Units: 3-0-9
______
Both active and passive acoustic methods of measuring marine organisms, the seafloor, and their interactions are reviewed. Acoustic methods of detecting, observing, and quantifying marine biological organisms are described, as are acoustic methods of measuring geological properties of the seafloor, including depth, and surficial and volumetric composition. Interactions are also described, including effects of biological scatterers on geological measurements, and effects of seafloor scattering on measurements of biological scatterers on, in, or immediately above the seafloor. Methods of determining small-scale material properties of organisms and the seafloor are outlined. Operational methods are emphasized, and corresponding measurement theory is described. Case studies are used in illustration. Principles of acoustic-system calibration are elaborated.
K. G. Foote, Woods Hole Staff

2.684 Wave Scattering by Rough Surfaces and Inhomogeneous Media
______

Not offered academic year 2017-2018Graduate (Spring) Can be repeated for credit
Prereq: 2.066 or permission of instrctor
Units: 3-0-9
______
An advanced-level subject designed to give students a working knowledge of current techniques in this area. Material is presented principally in the context of ocean acoustics, but can be used in other acoustic and electromagnetic applications. Includes fundamentals of wave propagation through, and/or scattering by: random media, extended coherent structures, rough surfaces, and discrete scatterers.
T. K. Stanton, A. C. Lavery, Woods Hole Staff

2.687 Time Series Analysis and System Identification
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: 6.011, 18.06
Units: 3-0-9
______
Covers matched filtering, power spectral (PSD) estimation, and adaptive signal processing / system identification algorithms. Algorithm development is framed as an optimization problem, and optimal and approximate solutions are described. Reviews time-varying systems, first and second moment representations of stochastic processes, and state-space models. Also covers algorithm derivation, performance analysis, and robustness to modeling errors. Algorithms for PSD estimation, the LMS and RLS algorithms, and the Kalman Filter are treated in detail.
J. C. Preisig, Woods Hole Staff

2.688 Principles of Oceanographic Instrument Systems -- Sensors and Measurements
______

Graduate (Fall)
Prereq: 18.075, 2.671
Units: 3-3-6
Meets at WHOI. TBA.
______
Introduces theoretical and practical principles of design of oceanographic sensor systems. Transducer characteristics for acoustic, current, temperature, pressure, electric, magnetic, gravity, salinity, velocity, heat flow, and optical devices. Limitations on these devices imposed by ocean environment. Signal conditioning and recording; noise, sensitivity, and sampling limitations; standards. Principles of state-of-the-art systems being used in physical oceanography, geophysics, submersibles, acoustics discussed in lectures by experts in these areas. Day cruises in local waters during which the students will prepare, deploy and analyze observations from standard oceanographic instruments constitute the lab work for this subject.
H. Singh, R. Geyer, A. Michel
No textbook information available

2.689[J] Projects in Oceanographic Engineering
______

Graduate (Fall, Summer) Can be repeated for credit
(Same subject as 1.699[J])
Prereq: Permission of instructor
Units arranged [P/D/F]
Meets at WHOI. TBA.
______
Projects in oceanographic engineering, carried out under supervision of Woods Hole Oceanographic Institution staff. Given at Woods Hole Oceanographic Institution.
J. Preisig, Woods Hole Staff
No textbook information available

2.690 Corrosion in Marine Engineering
______

Graduate (Summer)
Prereq: 3.012, permission of instructor
Units: 3-0-3
______
Introduction to forms of corrosion encountered in marine systems material selection, coatings and protection systems. Case studies and causal analysis developed through student presentations.
J. Page, T. Eagar
No textbook information available
______
Summer 2016 Description for Corrosion in Marine Engineering
Prereq:3.012, permission of instructor
Units: 3-0-3


Introduction to forms of corrosion encountered in marine systems material selection, coatings and protection systems. Case studies and causal analysis developed through student presentations.

T. Eager
Section: MTWThF 8:00 AM-10:00 AM Room 4-145 From 06-JUN-16 Thru 22-JUL-16
No textbook information available

Naval Architecture

2.700 Principles of Naval Architecture
______

Undergrad (Fall)
(Subject meets with2.701)
Prereq: 2.002
Units: 4-2-6
Lecture: MW9.30-11 (5-217) Recitation: F1 (5-217)
______
F. S. Hover, A. H. Techet, J. Harbour, P. D. Sclavounos, J. Page
Textbooks (Fall 2016)

2.701 Principles of Naval Architecture
______

Graduate (Fall)
(Subject meets with2.700)
Prereq: 2.002
Units: 4-2-6
Lecture: MW9.30-11 (5-217) Recitation: F1 (5-217)
______
Presents principles of naval architecture, ship geometry, hydrostatics, calculation and drawing of curves of form, intact and damage stability, hull structure strength calculations and ship resistance. Introduces computer-aided naval ship design and analysis tools. Projects include analysis of ship lines drawings, calculation of ship hydrostatic characteristics, analysis of intact and damaged stability, ship model testing, and hull structure strength calculations. Students taking graduate version complete additional assignments.
J. Harbour, S. Brizzolara, J. Page
Textbooks (Fall 2016)

2.702 Systems Engineering and Naval Ship Design
______

Graduate (Spring)
Prereq: 2.701
Units: 3-3-3
______
Introduces principles of systems engineering and ship design with an overview of naval ship design and acquisition processes, requirements setting, formulation of a systematic plan, design philosophy and constraints, formal decision making methods, selection criteria, optimization, variant analysis, trade-offs, analysis of ship design trends, risk, and cost analysis. Emphasizes the application of principles through completion of a design exercise and project.
J. Harbour, J. Page

2.703 Principles of Naval Ship Design
______

Graduate (Fall)
Prereq: 2.082, 2.20, 2.611, 2.702
Units: 4-2-6
Lecture: TR11-12.30 (5-217)
______
Covers the design of surface ship platforms for naval applications. Includes topics such as hull form selection and concept design synthesis, topside and general arrangements, weight estimation, and technical feasibility analyses (including strength, stability, seakeeping, and survivability.). Practical exercises involve application of design principles and utilization of advanced computer-aided ship design tools.
J. Harbour, J. Page
No required or recommended textbooks

2.704 Projects in Naval Ship Conversion Design
______

Graduate (IAP, Spring)
Prereq: 2.703
Units: 1-6-5
______
Focuses on conversion design of a naval ship. A new mission requirement is defined, requiring significant modification to an existing ship. Involves requirements setting, design plan formulation and design philosophy, and employs formal decision-making methods. Technical aspects demonstrate feasibility and desirability. Includes formal written and verbal reports and team projects.
J. Harbour, J. Page
No textbook information available

2.705 Projects in New Concept Naval Ship Design
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 2.704
Units arranged
TBA.
______
Focus on preliminary design of a new naval ship, fulfilling a given set of mission requirements. Design plan formulation, system level trade-off studies, emphasizes achieving a balanced design and total system integration. Formal written and oral reports. Team projects extend over three terms.
J. Harbour, J. Page
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

2.707 Submarine Structural Acoustics
______

Not offered academic year 2016-2017Graduate (Spring); first half of term
Prereq: 2.066
Units: 2-0-4
______
Introduction to the acoustic interaction of submerged structures with the surrounding fluid. Fluid and elastic wave equations. Elastic waves in plates. Radiation and scattering from planar structures as well as curved structures such as spheres and cylinders. Acoustic imaging of structural vibrations. Students can take 2.085 in the second half of term.
H. Schmidt

2.708 Traditional Naval Architecture Design
______

Graduate (IAP)
Prereq: None
Units: 2-0-1 [P/D/F]
______
Week-long intensive introduction to traditional design methods in which students hand draw a lines plan of a N. G. Herreshoff (MIT Class of 1870) design based on hull shape offsets taken from his original design model. After completing the plan, students then carve a wooden half-hull model of the boat design. Covers methods used to develop hull shape analysis data from lines plans. Provides students with instruction in safe hand tool use and how to transfer their lines to 3D in the form of their model. Limited to 15.
K. Hasselbalch, J. Harbour

Optics

2.71 Optics
______

Undergrad (Fall)
(Subject meets with2.710)
Prereq: Physics II (GIR); 18.03; 2.004, 2.04A, 2.04B, or permission of instructor
Units: 3-0-9
Lecture: MW9.30-11 (1-135)
______
Textbooks (Fall 2016)

2.710 Optics
______

Graduate (Fall)
(Subject meets with2.71)
Prereq: Physics II (GIR); 18.03; 2.004, 2.04A, 2.04B, or permission of instructor
Units: 3-0-9
Lecture: MW9.30-11 (1-135)
______
Introduction to optical science with elementary engineering applications. Geometrical optics: ray-tracing, aberrations, lens design, apertures and stops, radiometry and photometry. Wave optics: basic electrodynamics, polarization, interference, wave-guiding, Fresnel and Fraunhofer diffraction, image formation, resolution, space-bandwidth product. Emphasis on analytical and numerical tools used in optical design. Graduate students are required to complete additional assignments with stronger analytical content, and an advanced design project.
G. Barbastathis, P. T. So
Textbooks (Fall 2016)

2.715[J] Optical Microscopy and Spectroscopy for Biology and Medicine
______

Graduate (Spring)
Not offered regularly; consult department
(Same subject as20.487[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces the theory and the design of optical microscopy and its applications in biology and medicine. The course starts from an overview of basic optical principles allowing an understanding of microscopic image formation and common contrast modalities such as dark field, phase, and DIC. Advanced microscopy imaging techniques such as total internal reflection, confocal, and multiphoton will also be discussed. Quantitative analysis of biochemical microenvironment using spectroscopic techniques based on fluorescence, second harmonic, Raman signals will be covered. We will also provide an overview of key image processing techniques for microscopic data.
P. T. So, C. Sheppard

2.717 Optical Engineering
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 2.710 or permission of instructor
Units: 3-0-9
TBA.
______
Theory and practice of optical methods in engineering and system design. Emphasis on diffraction, statistical optics, holography, and imaging. Provides engineering methodology skills necessary to incorporate optical components in systems serving diverse areas such as precision engineering and metrology, bio-imaging, and computing (sensors, data storage, communication in multi-processor systems). Experimental demonstrations and a design project are included.
P. T. So, G. Barbastathis

2.718 Photonic Materials
______

Undergrad (Fall)
(Subject meets with2.719)
Prereq: 2.003, 8.03, 6.161, or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (1-134)
______
Textbooks (Fall 2016)

2.719 Photonic Materials
______

Graduate (Fall)
(Subject meets with2.718)
Prereq: 2.003, 8.03, 6.161, or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (1-134)
______
Provides a review of Maxwell's equations and the Helmholtz wave equation. Optical devices: waveguides and cavities, phase and group velocity, causality, and scattering. Light-matter interaction in bulk, surface, and subwavelength-structured matter. Effective media, dispersion relationships, wavefronts and rays, eikonal description of light propagation, phase singularities. Transformation optics, gradient effective media. Includes description of the experimental tools for realization and measurement of photonic materials and effects. Students taking graduate version complete additional assignments.
G. Barbastathis, N. Fang
Textbooks (Fall 2016)

Design

2.70 FUNdaMENTALS of Precision Product Design
______

Undergrad (Spring)
(Subject meets with2.77)
Prereq: 2.008
Units: 3-3-6
______

2.77 FUNdaMENTALS of Precision Product Design
______

Graduate (Spring)
(Subject meets with2.70)
Prereq: 2.008
Units: 3-3-6
______
Examines design, selection, and combination of machine elements to produce a robust precision system. Introduces process, philosophy and physics-based principles of design to improve/enable renewable power generation, energy efficiency, and manufacturing productivity. Topics include linkages, power transmission, screws and gears, actuators, structures, joints, bearings, error apportionment, and error budgeting. Considers each topic with respect to its physics of operation, mechanics (strength, deformation, thermal effects) and accuracy, repeatability, and resolution. Includes guest lectures from practicing industry and academic leaders. Students design, build, and test a small benchtop precision machine, such as a heliostat for positioning solar PV panels or a two or three axis machine. Prior to each lecture, students review the pre-recorded detailed topic materials and then converge on what parts of the topic they want covered in extra depth in lecture. Students are assessed on their preparation for and participation in class sessions. Students taking graduate version complete additional assignments. Enrollment limited.
A. Slocum

2.72 Elements of Mechanical Design
______

Undergrad (Spring)
(Subject meets with2.720)
Prereq: 2.005 or 2.051; 2.008;Coreq: 2.671
Units: 3-3-6
URL: http://pcsl.mit.edu/2_72/index.html
______
Advanced study of modeling, design, integration, and best practices for use of machine elements, such as bearings, bolts, belts, flexures, and gears. Modeling and analysis is based upon rigorous application of physics, mathematics, and core mechanical engineering principles, which are reinforced via laboratory experiences and a design project in which students model, design, fabricate, and characterize a mechanical system that is relevant to a real-world application. Activities and quizzes are directly related to, and coordinated with, the project deliverables. Develops the ability to synthesize, model and fabricate a design subject to engineering constraints (e.g., cost, time, schedule). Students taking graduate version complete additional assignments. Enrollment limited.
M. L. Culpepper

2.720 Elements of Mechanical Design
______

Graduate (Spring)
(Subject meets with2.72)
Prereq: permission of instructor
Units: 3-3-6
______
Advanced study of modeling, design, integration, and best practices for use of machine elements, such as bearings, bolts, belts, flexures, and gears. Modeling and analysis is based upon rigorous application of physics, mathematics, and core mechanical engineering principles, which are reinforced via laboratory experiences and a design project in which students model, design, fabricate, and characterize a mechanical system that is relevant to a real-world application. Activities and quizzes are directly related to, and coordinated with, the project deliverables. Develops the ability to synthesize, model and fabricate a design subject to engineering constraints (e.g., cost, time, schedule). Students taking graduate version complete additional assignments.
M. L. Culpepper

2.722[J] D-Lab: Design
______

Undergrad (Spring)
(Same subject asEC.720[J])
Prereq: 2.670 or permission of the instructor
Units: 3-0-9
______
Addresses problems faced by underserved communities with a focus on design, experimentation, and prototyping processes. Particular attention placed on constraints faced when designing for developing countries. Multidisciplinary teams work on long-term projects in collaboration with community partners, field practitioners, and experts in relevant fields. Topics covered include design for affordability, manufacture, sustainability, and strategies for working effectively with community partners and customers. Students may continue projects begun in EC.701. Enrollment limited by lottery; must attend first class session.
A. B. Smith, M. McCambridge

2.723 Engineering Innovation and Design
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:2.723,6.902,16.662)
Prereq: None
Units: 3-0-3
Lecture: M EVE (7-9 PM) (32-155) Recitation: M EVE (9 PM) (32-155) or W EVE (7 PM) (2-105) or W EVE (8 PM) (2-105)
______
Project-based seminar in innovative design thinking develops students' ability to conceive, implement, and evaluate successful projects in any engineering discipline. Lectures focus on the iterative design process and techniques to enhance creative analysis. Students use this process to design and implement robust voice recognition applications using a simple web-based system. They also give presentations and receive feedback to sharpen their communication skills for high emotional and intellectual impact. Guest lectures illustrate multidisciplinary approaches to design thinking.
B. Kotelly
No textbook information available

2.729[J] D-Lab: Design for Scale
______

Undergrad (Fall)
(Same subject asEC.729[J])
Prereq: Permission of instructor
Units: 3-2-7
Lecture: TR11.30-1 (N51-350) Recitation: R1-2.30 (N51-350)
______
Focuses on product development of technologies for people in less industrialized markets. Students work in interdisciplinary teams to develop previously established prototypes or technologies towards manufacturing-ready product designs. Topics are presented within the context of the developing world and include technology feasibility and scalability assessment; value chain analysis; product specification; design for affordability, manufacturability, usability, and desirability; and product testing and manufacturing at various scales. Lessons are experiential and case study-based; taught by instructors with field experience and by industry experts from product development consulting firms and the consumer electronics industry.
M. McCambridge, M. Yang, H. Quintus-Bosz
No textbook information available

2.737 Mechatronics
______

Graduate (Fall)
Prereq: 6.071 or 6.002; 2.14, 6.302, or 16.30
Units: 3-5-4
Lecture: MW2.30-4 (1-246) Lab: T2-5 (1-004) or R2-5 (1-004)
______
Introduction to designing mechatronic systems, which require integration of the mechanical and electrical engineering disciplines within a unified framework. Significant laboratory-based design experiences form subject's core. Final project. Topics include: low-level interfacing of software with hardware; use of high-level graphical programming tools to implement real-time computation tasks; digital logic; analog interfacing and power amplifiers; measurement and sensing; electromagnetic and optical transducers; control of mechatronic systems. Limited to 20.
D. L. Trumper, K. Youcef-Toumi
No required or recommended textbooks

2.739[J] Product Design and Development
______

Graduate (Spring)
(Same subject as15.783[J])
Prereq: 2.009, 15.761, 15.778, 15.810, or permission of instructor
Units: 3-3-6
URL: http://web.mit.edu/15.783j/www/
______
Covers modern tools and methods for product design and development. Includes a cornerstone project in which teams conceive, design and prototype a physical product and/or service. Covers design thinking, product planning, identifying customer needs, concept generation, product architecture, industrial design, concept design, green design methods, and product management. Sloan students register via Sloan course bidding. Engineering students accepted via lottery based on WebSIS pre-registration.
S. Eppinger, M. C. Yang

2.74 Bio-inspired Robotics
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with2.740)
Prereq: 2.004 or permission of instructor
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Interdisciplinary approach to bio-inspired design, with emphasis on principle extraction applicable to various robotics research fields, such as robotics, prosthetics, and human assistive technologies. Focuses on three main components: biomechanics, numerical techniques that allow multi-body dynamics simulation with environmental interaction and optimization, and basic robotics techniques and implementation skills. Students integrate the components into a final robotic system project of their choosing through which they must demonstrate their understanding of dynamics and control and test hypothesized design principles. Students taking graduate version complete additional assignments. Enrollment may be limited due to laboratory capacity.
S. Kim

2.740 Bio-inspired Robotics
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with2.74)
Prereq: 2.004 or permission of instructor
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Interdisciplinary approach to bio-inspired design, with emphasis on principle extraction applicable to various robotics research fields, such as robotics, prosthetics, and human assistive technologies. Focuses on three main components: biomechanics, numerical techniques that allow multi-body dynamics simulation with environmental interaction and optimization, and basic robotics techniques and implementation skills. Students integrate the components into a final robotic system project of their choosing through which they must demonstrate their understanding of dynamics and control and test hypothesized design principles. Students taking graduate version complete additional assignments. Enrollment may be limited due to lab capacity.
S. Kim

2.744 Product Design
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 2.009
Units: 3-0-9
URL: http://me.mit.edu/2.744/
______
Project-centered subject addressing transformation of ideas into successful products which are properly matched to the user and the market. Students are asked to take a more complete view of a new product and to gain experience with designs judged on their aesthetics, ease of use, and sensitivities to the realities of the marketplace. Lectures on modern design process, industrial design, visual communication, form-giving, mass production, marketing, and environmentally conscious design.
D. R. Wallace

2.75[J] Medical Device Design
______

Graduate (Fall)
(Same subject as6.525[J],HST.552[J])
(Subject meets with2.750[J],6.025[J])
Prereq: 2.72, 6.101, 6.111, 6.115, 22.071, or permission of instructor
Units: 3-0-9
2.75: URL: https://web.mit.edu/2.75/
2.750: URL: https://web.mit.edu/2.75/
2.75: Lecture: MW1-2.30 (3-270)
2.750: Lecture: MW1-2.30 (3-270)
______
2.75: No required or recommended textbooks
2.750: No required or recommended textbooks

2.750[J] Medical Device Design
______

Undergrad (Fall)
(Same subject as6.025[J])
(Subject meets with2.75[J],6.525[J],HST.552[J])
Prereq: 2.72, 6.101, 6.111, 6.115, 22.071, or permission of instructor
Units: 3-0-9
2.75: URL: https://web.mit.edu/2.75/
2.750: URL: https://web.mit.edu/2.75/
2.75: Lecture: MW1-2.30 (3-270)
2.750: Lecture: MW1-2.30 (3-270)
______
Application of mechanical and electrical engineering fundamentals to the design of medical devices that address clinical needs. Throughout the term, students work in small teams on a major project to translate a clinical challenge into a proof-of-concept prototype device. Students conduct user analysis, develop design specifications, and follow a structured process to cultivate creative designs and apply analytical techniques to optimize them. They deepen their understanding of art and intellectual property by researching prior representations. Develops practical skills in prototyping and testing as well as project management. Includes lectures, problem sets and exams that focus on design fundamentals. Instruction and practice in written and oral communication provided. Students taking graduate version complete additional assignments. Enrollment limited.
A. H. Slocum, G. Hom
2.75: No required or recommended textbooks
2.750: No required or recommended textbooks

2.752 Development of Mechanical Products
______

Undergrad (Spring)
(Subject meets with2.753)
Prereq: 2.750, 2.009, or permission of instructor
Units: 3-0-9
______

2.753 Development of Mechanical Products
______

Graduate (Spring)
(Subject meets with2.752)
Prereq: 2.750, 2.009, or permission of instructor
Units: 3-0-9
______
Focuses on evolving a product from proof-of-concept to beta prototype: Includes team building, project planning, budgeting, resource planning; models for scaling, tolerancing and reliability, patents, business planning. Students/teams start with a proof-of-concept product they bring to class or select from projects provided by instructor. In lieu of taking 12 units of 2.THU, Course 2 majors taking 2.752 may write a bachelor's thesis that documents their contributions to the product developed in the team project. Students taking the graduate version complete additional assignments. Enrollment limited.
A. Slocum

2.76 Global Engineering
______

Graduate (Fall)
(Subject meets with2.760)
Prereq: 2.008 or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (3-333)
______
Combines rigorous engineering theory and user-centered product design to create technologies for developing and emerging markets. Covers machine design theory to parametrically analyze technologies; bottom-up/top-down design processes; engagement of stakeholders in the design process; socioeconomic factors that affect adoption of products; and developing/emerging market dynamics and their effect on business and technology. Includes guest lectures from subject matter experts in relevant fields and case studies on successful and failed technologies. Student teams apply course material to term-long projects to create new technologies, developed in collaboration with industrial partners and other stakeholders in developing/emerging markets. Students taking graduate version complete additional assignments.
A. Winter
Textbooks (Fall 2016)

2.760 Global Engineering
______

Undergrad (Fall)
(Subject meets with2.76)
Prereq: 2.008 or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (3-333)
______
Combines rigorous engineering theory and user-centered product design to create technologies for developing and emerging markets. Covers machine design theory to parametrically analyze technologies; bottom-up/top-down design processes; engagement of stakeholders in the design process; socioeconomic factors that affect adoption of products; and developing/emerging market dynamics and their effect on business and technology. Includes guest lectures from subject matter experts in relevant fields and case studies on successful and failed technologies. Student teams apply course material to term-long projects to create new technologies, developed in collaboration with industrial partners and other stakeholders in developing/emerging markets. Students taking graduate version complete additional assignments.
A. Winter
No textbook information available

Bioengineering

2.772[J] Thermodynamics of Biomolecular Systems
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
(Same subject as20.110[J])
Prereq: Calculus II (GIR), Chemistry (GIR), Physics I (GIR)
Units: 5-0-7
Lecture: MWF10 (4-270) Recitation: TR10 (26-168) or TR1 (66-154) or TR4 (56-169) +final
______
Equilibrium properties of macroscopic and microscopic systems. Basic thermodynamics: state of a system, state variables. Work, heat, first law of thermodynamics, thermochemistry. Second and third law of thermodynamics: entropy and its statistical basis, Gibbs function. Chemical equilibrium of reactions in gas and solution phase. Macromolecular structure and interactions in solution. Driving forces for molecular self-assembly. Binding cooperativity, solvation, titration of macromolecules.
Fall:M. Birnbaum C. Voigt
Spring:E. Alm, C. Voigt
No textbook information available

2.78[J] Principles and Practice of Assistive Technology
(New)
______

Undergrad (Fall)
(Same subject as6.811[J],HST.420[J])
Prereq: Permission of instructor
Units: 2-4-6
Lecture: M2 (32-144) Lab: W2-5 (32-044)
______
Students work closely with people with disabilities to develop assistive and adaptive technologies that help them live more independently. Covers design methods and problem-solving strategies; human factors; human-machine interfaces; community perspectives; social and ethical aspects; and assistive technology for motor, cognitive, perceptual, and age-related impairments. Prior knowledge of one or more of the following areas useful: software; electronics; human-computer interaction; cognitive science; mechanical engineering; control; or MIT hobby shop, MIT PSC, or other relevant independent project experience.
R. C. Miller, J. E. Greenberg, J. J. Leonard
Textbooks (Fall 2016)

2.782[J] Design of Medical Devices and Implants
______

Graduate (Spring)
(Same subject as3.961[J],HST.524[J])
Prereq: Chemistry (GIR), Biology (GIR), Physics I (GIR); or permission of instructor
Units: 3-0-9
______
Solution of clinical problems by use of implants and other medical devices. Systematic use of cell-matrix control volumes. The role of stress analysis in the design process. Anatomic fit: shape and size of implants. Selection of biomaterials. Instrumentation for surgical implantation procedures. Preclinical testing for safety and efficacy: risk/benefit ratio assessment. Evaluation of clinical performance: design of clinical trials. Project materials drawn from orthopedic devices, soft tissue implants, artificial organs, and dental implants.
I. V. Yannas, M. Spector

2.785[J] Cell-Matrix Mechanics
______

Graduate (Fall)
(Same subject as3.97[J],HST.523[J])
Prereq: 2.001, or 2.01 and 2.02A; Chemistry (GIR), Biology (GIR); or permission of instructor
Units: 3-0-9
Lecture: TR11-12.30 (1-371)
______
Mechanical forces play a decisive role during development of tissues and organs, during remodeling following injury as well as in normal function. A stress field influences cell function primarily through deformation of the extracellular matrix to which cells are attached. Deformed cells express different biosynthetic activity relative to undeformed cells. The unit cell process paradigm combined with topics in connective tissue mechanics form the basis for discussions of several topics from cell biology, physiology, and medicine.
I. V. Yannas, M. Spector
No required or recommended textbooks

2.79[J] Biomaterials: Tissue Interactions
______

Graduate (Fall)
(Same subject as3.96[J],HST.522[J])
Prereq: Chemistry (GIR), Biology (GIR), Physics I (GIR); or permission of instructor
Units: 3-0-9
Lecture: TR2.30-4 (3-370)
______
Principles of materials science and cell biology underlying the development and implementation of biomaterials for the fabrication of medical devices/implants, including artificial organs and matrices for tissue engineering and regenerative medicine. Employs a conceptual model, the "unit cell process for analysis of the mechanisms underlying wound healing and tissue remodeling following implantation of biomaterials/devices in various organs, including matrix synthesis, degradation, and contraction. Methodology of tissue and organ regeneration. Discusses methods for biomaterials surface characterization and analysis of protein adsorption on biomaterials. Design of implants and prostheses based on control of biomaterials-tissue interactions. Comparative analysis of intact, biodegradable, and bioreplaceable implants by reference to case studies. Criteria for restoration of physiological function for tissues and organs.
I. V. Yannas, M. Spector
Textbooks (Fall 2016)

2.791[J] Cellular Neurophysiology
______

Undergrad (Fall)
(Same subject as6.021[J],20.370[J])
(Subject meets with2.794[J],6.521[J],20.470[J],HST.541[J])
Prereq: Physics II (GIR); 18.03; 2.005, 6.002, 6.003, 6.071, 10.301, 20.110, or permission of instructor
Units: 5-2-5
Lecture: MWF10 (32-144) Lab: TBA Recitation: T12 (34-303) or T4 (34-302) +final
______
Integrated overview of the biophysics of cells from prokaryotes to neurons, with a focus on mass transport and electrical signal generation across cell membrane. First half of course focuses on mass transport through membranes: diffusion, osmosis, chemically mediated, and active transport. Second half focuses on electrical properties of cells: ion transport to action potentials in electrically excitable cells. Synaptic transmission. Electrical properties interpreted via kinetic and molecular properties of single voltage-gated ion channels. Laboratory and computer exercises illustrate the concepts. Students taking graduate version complete different assignments. Preference to juniors and seniors.
J. Han, T. Heldt, J. Voldman
Textbooks (Fall 2016)

2.792[J] Quantitative Systems Physiology
______

Undergrad (Spring)
(Same subject as6.022[J],HST.542[J])
(Subject meets with2.796[J],6.522[J])
Prereq: Physics II (GIR), 18.03, or permission of instructor
Units: 4-2-6
URL: http://web.mit.edu/6.022j/www/
______
Application of the principles of energy and mass flow to major human organ systems. Mechanisms of regulation and homeostasis. Anatomical, physiological and pathophysiological features of the cardiovascular, respiratory and renal systems. Systems, features and devices that are most illuminated by the methods of physical sciences. Laboratory work includes some animal studies. Students taking graduate version complete additional assignments.
T. Heldt, R. G. Mark, C. M. Stultz

2.793[J] Fields, Forces and Flows in Biological Systems
______

Undergrad (Spring)
(Same subject as6.023[J],20.330[J])
Prereq: Physics II (GIR); 2.005, 6.021, or permission of instructor,Coreq: 20.309
Units: 4-0-8
______
Introduction to electric fields, fluid flows, transport phenomena and their application to biological systems. Flux and continuity laws, Maxwell's equations, electro-quasistatics, electro-chemical-mechanical driving forces, conservation of mass and momentum, Navier-Stokes flows, and electrokinetics. Applications include biomolecular transport in tissues, electrophoresis, and microfluidics.
J. Han, S. Manalis

2.794[J] Cellular Neurophysiology
______

Graduate (Fall)
(Same subject as6.521[J],20.470[J],HST.541[J])
(Subject meets with2.791[J],6.021[J],20.370[J])
Prereq: Physics II (GIR); 18.03; 2.005, 6.002, 6.003, 6.071, 10.301, 20.110, or permission of instructor
Units: 5-2-5
Lecture: MWF10 (32-144) Lab: TBA Recitation: T12 (34-303) or T4 (34-302) +final
______
Meets with undergraduate subject 6.021J. Requires the completion of more advanced home problems and/or an additional project.
J. Han, T. Heldt
Textbooks (Fall 2016)

2.795[J] Fields, Forces, and Flows in Biological Systems
______

Graduate (Fall)
(Same subject as6.561[J],10.539[J],20.430[J])
Prereq: 6.013, 2.005, 10.302, or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (32-124)
______
Molecular diffusion, diffusion-reaction, conduction, convection in biological systems; fields in heterogeneous media; electrical double layers; Maxwell stress tensor, electrical forces in physiological systems. Fluid and solid continua: equations of motion useful for porous, hydrated biological tissues. Case studies of membrane transport, electrode interfaces, electrical, mechanical, and chemical transduction in tissues, convective-diffusion/reaction, electrophoretic, electroosmotic flows in tissues/MEMs, and ECG. Electromechanical and physicochemical interactions in cells and biomaterials; musculoskeletal, cardiovascular, and other biological and clinical examples.
M. Bathe, A. J. Grodzinsky
Textbooks (Fall 2016)

2.796[J] Quantitative Physiology: Organ Transport Systems
______

Graduate (Spring)
(Same subject as6.522[J])
(Subject meets with2.792[J],6.022[J],HST.542[J])
Prereq: 2.006 or 6.013; 6.021
Units: 4-2-6
______
Application of the principles of energy and mass flow to major human organ systems. Mechanisms of regulation and homeostasis. Anatomical, physiological and pathophysiological features of the cardiovascular, respiratory and renal systems. Systems, features and devices that are most illuminated by the methods of physical sciences. Laboratory work includes some animal studies. Students taking graduate version complete additional assignments.
T. Heldt, R. G. Mark, C. M. Stultz

2.797[J] Molecular, Cellular, and Tissue Biomechanics
______

Undergrad (Spring)
(Same subject as3.053[J],6.024[J],20.310[J])
Prereq: 2.370 or 2.772J; 18.03 or 3.016; Biology (GIR)
Units: 4-0-8
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, A. J. Grodzinsky, K. Van Vliet

2.798[J] Molecular, Cellular, and Tissue Biomechanics
______

Graduate (Fall)
(Same subject as3.971[J],6.524[J],10.537[J],20.410[J])
Prereq: Biology (GIR); 2.002, 2.006, 6.013, 10.301, or 10.302
Units: 3-0-9
Lecture: TR10.30-12 (2-143)
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, K. J. Van Vliet
No textbook information available

2.799 The Cell as a Machine
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 5.07, 18.03, or 7.05
Units: 3-3-6
______
Examines a variety of essential cellular functions from the perspective of the cell as a machine. Includes phenomena such as nuclear organization, protein synthesis, cell and membrane mechanics, cell migration, cell cycle control, cell transformation. Lectures are provided by video twice per week; live 3-hour recitation one evening per week. Course is taken simultaneously by students at multiple universities; homework and take-home exams common to all students. Preference to students in Courses 2 and 20.
R. Kamm, M. Sheetz, H. Yu


left arrow|2.000-2.199|2.20-2.7999|2.80-2.999 plus Thesis, UROP, UPOP|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 2: Mechanical Engineering
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Course 2: Mechanical Engineering
Fall 2016


Manufacturing

2.810 Manufacturing Processes and Systems
______

Graduate (Fall)
Prereq: 2.001, 2.006, 2.008
Units: 3-3-6
Lecture: MW2.30-4 (37-212) Lab: M9-12 (35-125) or W9-12 (35-125) or R9-12 (35-125) or F9-12 (35-125)
______
Introduction to manufacturing processes and manufacturing systems including assembly, machining, injection molding, casting, thermoforming, and more. Emphasis on the physics and randomness and how they influence quality, rate, cost, and flexibility. Attention to the relationship between the process and the system, and the process and part design. Project (in small groups) requires fabrication (and some design) of a product using several different processes (as listed above). Enrollment may be limited due to laboratory constraints.
T. G. Gutowski
Textbooks (Fall 2016)

2.813 Energy, Materials, and Manufacturing
______

Undergrad (Spring)
(Subject meets with2.83)
Prereq: 2.008 or permission of instructor
Units: 3-0-9
______
Introduction to the major dilemma that faces manufacturing and society for the 21st century: how to support economic development while protecting the environment. Subject addresses industrial ecology, materials flows, life-cycle analysis, thermodynamic analysis and exergy accounting, manufacturing process performance, product design analysis, design for the environment, recycling and ecological economics. Combines lectures and group discussions of journal articles and selected literature, often with opposing views. Graduate students complete term-long project with report required for graduate credit.
T. G. Gutowski

2.821[J] Selection and Processing of Structural Materials
______

Graduate (Fall, Spring, Summer) Can be repeated for credit; partial term
(Same subject as3.371[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: MWF9 (4-145) Recitation: TR9 (4-145)
______
Discusses selection design and processing for structural materials, including casting, forging, rolling, drawing, extrusion, powder consolidation, welding, brazing, soldering, wear, corrosion, non-destructive testing and fracture. Emphasizes the underlying science of a given process rather than a detailed description of the technique or equipment. Presented in modules; repeatable for credit one time with permission of instructor, provided three different modules are selected the second term.
T. Eagar
No required or recommended textbooks
______
Summer 2016 Description for Selection and Processing of Structural Materials
(Same subject as 2.821J) (Subject meets with 3.S171)
Prereq:Permission of instructor
Units: 3-0-9
Can be repeated for credit

Discusses selection design and processing for structural materials, including casting, forging, rolling, drawing, extrusion, powder consolidation, welding, brazing, soldering, wear, corrosion, non-destructive testing and fracture. Emphasizes the underlying science of a given process rather than a detailed description of the technique or equipment. Presented in modules; repeatable for credit one time with permission of instructor, provided three different modules are selected the second term.

T. Eager
Section: MTWThF 8:00 AM-10:00 AM Room 4-145 From 06-JUN-16 Thru 22-JUL-16

2.83 Energy, Materials and Manufacturing
______

Graduate (Spring)
(Subject meets with2.813)
Prereq: 2.008 or permission of instructor
Units: 3-0-9
______
Introduction to the major dilemma that faces manufacturing and society for the 21st century: how to support economic development while protecting the environment. Subject addresses industrial ecology, materials flows, life-cycle analysis, thermodynamic analysis and exergy accounting, manufacturing process performance, product design analysis, design for the environment, recycling and ecological economics. Combines lectures and group discussions of journal articles and selected literature, often with opposing views. Graduate students complete term-long project with report required for graduate credit.
T. G. Gutowski

2.830[J] Control of Manufacturing Processes
______

Graduate (Spring)
(Same subject as6.780[J])
Prereq: 2.008, 6.041B, 6.152, or 15.064
Units: 3-0-9
______
Statistical modeling and control in manufacturing processes. Use of experimental design and response surface modeling to understand manufacturing process physics. Defect and parametric yield modeling and optimization. Forms of process control, including statistical process control, run by run and adaptive control, and real-time feedback control. Application contexts include semiconductor manufacturing, conventional metal and polymer processing, and emerging micro-nano manufacturing processes.
D. E. Hardt, D. S. Boning

2.851[J] System Optimization and Analysis for Operations
______

Graduate (Summer)
(Same subject as15.066[J])
Prereq: Calculus II (GIR)
Units: 4-0-8
______
Introduction to mathematical modeling, optimization, and simulation, as applied to manufacturing. Specific methods include linear programming, network flow problems, integer and nonlinear programming, discrete-event simulation, heuristics and computer applications for manufacturing processes and systems. Restricted to Leaders for Global Operations students.
V. Farias
No textbook information available

2.852 Manufacturing Systems Analysis
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 6.041B or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/manuf-sys/www/syllabus.html
______
Models of manufacturing systems, including transfer lines and flexible manufacturing systems. Calculation of performance measures, including throughput, in-process inventory, and meeting production commitments. Real-time control of scheduling. Effects of machine failure, set-ups, and other disruptions on system performance.
S. B. Gershwin

2.853 Introduction to Manufacturing Systems
______

Undergrad (Fall)
(Subject meets with2.854)
Prereq: 2.008
Units: 3-0-9
Lecture: TR9.30-11 (3-333)
______
No textbook information available

2.854 Introduction to Manufacturing Systems
______

Graduate (Fall)
(Subject meets with2.853)
Prereq: Undergraduate mathematics
Units: 3-0-9
Lecture: TR9.30-11 (3-333)
______
Provides ways to analyze manufacturing systems in terms of material flow and storage, information flow, capacities, and times and durations of events. Fundamental topics include probability, inventory and queuing models, forecasting, optimization, process analysis, and linear and dynamic systems. Factory planning and scheduling topics include flow planning, bottleneck characterization, buffer and batch-size tactics, seasonal planning, and dynamic behavior of production systems. Graduate students are required to complete additional assignments.
S. B. Gershwin
No textbook information available

2.888 Professional Seminar in Global Manufacturing Innovation and Entrepreneurship
______

Graduate (Spring)
Prereq: None
Units: 2-0-1
______
Covers a broad range of topics in modern manufacturing, from models and structures for 21st-century operations, to case studies in leadership from the shop floor to the executive office. Also includes global perspectives from Asia, Europe and North America, with guest speakers from all three regions. Explores opportunities for new ventures in manufacturing. Intended primarily for Master of Engineering in Manufacturing students.
D. E. Hardt, S. B. Gershwin

2.890[J] Global Operations Leadership Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as10.792[J],15.792[J],16.985[J])
Prereq: None
Units arranged [P/D/F]
Lecture: M EVE (4-6 PM) (E62-262)
______
Integrative forum in which worldwide leaders in business, finance, government, sports, and education share their experiences and insights with students aspiring to run global operations. Students play a large role in managing the seminar. Preference to LGO students.
T. Roemer
No textbook information available

Engineering Management

2.900 Ethics for Engineers
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.082,2.900,6.904,10.01,22.014)
Prereq: None
Units: 2-0-4
Lecture: M3-5 (66-144, 36-153) or T3-5 (37-212) or T EVE (7.30-9.30 PM) (66-144) or W3-5 (36-153)
______
Integrates classical readings that provide an overview of ethics with a survey of case studies that focus on ethical problems arising in the practice of engineering. Readings taken from a variety of sources, such as Aristotle, Machiavelli, Bacon, Hobbes, Locke, the Founding Fathers, and the Bible. Case studies include written analyses and films that address engineering disasters, biotechnology, court cases, ethical codes, and the ultimate scope and aims of engineering.
D. Doneson, B. L. Trout
No textbook information available

2.912[J] Venture Engineering
(New)
______

Undergrad (Spring)
(Same subject as15.373[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Develops the capability to move from testing ideas to assembling a venture as a system comprised of technological, human, social, regulatory, managerial, and financial processes and flows that affect costs, revenues, and value. Begins with a focus on leadership, addressing key issues involved in recruiting and building a founder team and its early employees. Fosters understanding of financial resource needs for the new enterprise and methods for raising funds. Students engage in a venture planning activity in which they must demonstrate their understanding of the concepts covered in class.
F. Murray

2.916[J] Funding Strategies for Startups
______

Graduate (Spring); second half of term
(Same subject as10.407[J])
Prereq: None
Units: 2-0-4
______
Introduction to the substance and process of funding technology startups. Topics include a comparative analysis of various sources of capital; templates to identify the optimal investor; legal frameworks, US and offshore, of the investment process and its related jargon; an introduction to understanding venture capital as a business; and market practice and standards for term sheet negotiation. Emphasizes strategy as well as tactics necessary to negotiate and build effective, long-term relationships with investors, particularly venture capital firms (VCs).
S. Loessberg, D. P. Hart

2.96 Management in Engineering
______

Undergrad (Fall)
Engineering School-Wide Elective Subject.
(Offered under:2.96,6.930,10.806,16.653)
Prereq: None
Units: 3-1-8
Lecture: MW11-12.30 (35-225) Lab: M4 (35-308) or T10 (1-273) or R4 (1-371) or F1 (1-132) or F2 (1-132)
______
No textbook information available

2.961 Management in Engineering
______

Graduate (Fall)
Prereq: None
Units: 3-1-8
Lecture: MW11-12.30 (35-225) Lab: M4 (35-310)
______
Introduction and overview of engineering management. Financial principles, management of innovation, technical strategy and best management practices. Case study method of instruction emphasizes participation in class discussion. Focus is on the development of individual skills and management tools.
J.-H. Chun, H. S. Marcus
No textbook information available

2.965[J] Global Supply Chain Management
______

Graduate (Spring)
(Same subject as1.265[J],15.765[J],SCM.265[J])
Prereq: 1.260, 1.261, 15.761, 15.778, or permission of instructor
Units: 2-0-4
______
Focuses on the planning, processes, and activities of supply chain management for companies involved in international commerce. Students examine the end-to-end processes and operational challenges in managing global supply chains, such as the basics of global trade, international transportation, duty, taxes, trade finance and hedging, currency issues, outsourcing, cultural differences, risks and security, and green supply chains issues. Highly interactive format features student-led discussions, staged debates, and a mock trial. Includes assignments on case studies and sourcing analysis, as well as projects and a final exam.
B. Arntzen

Advanced Topics and Special Subjects

2.98 Sports Technology: Engineering & Innovation
(New)
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: F3-5 (1-390)
______
Examines the future of sports technology across technical disciplines including mechanical design, biomechanics, quantified self, sports analytics, and business strategies. Leaders in the field will be brought in to discuss various industries, career pathways and opportunities for innovation in the field. Class projects will explore and potentially kickoff larger research and/or entrepreneurial initiatives. Open to undergraduate and graduate students.
A. Hosoi, C. Chase
No textbook information available

2.981 New England Coastal Ecology
______

Undergrad (IAP)
Prereq: None
Units: 2-0-1 [P/D/F]
______
Provides exposure to marine communities found along the coast of New England and how they fit into global patterns. Focuses on the ecology of salt marshes and rocky shores, and the biology of plants and animals that live in these complex habitats. Prepares students to recognize common inhabitants of these two communities and develops understanding of the major environmental factors affecting them, the types of ecological services they provide, and likely impacts of current and future climate change. Includes visits to field and research centers. Limited to 20.
Consult C. Bastidas

2.990 Practical Work Experience
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units: 0-1-0 [P/D/F]
TBA.
______
For Mechanical Engineering undergraduates participating in curriculum-related off-campus work experiences in mechanical engineering. Before enrolling, students must have an employment offer from a company or organization and must find a Mech E supervisor. Upon completion of the work the student must submit a detailed design notebook, approved by the MIT supervisor. Subject to departmental approval. Consult Department Undergraduate Office for details on procedures and restrictions.
A. Slocum
No textbook information available

2.993, 2.994 Independent Study
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
2.993: TBA.
2.994: TBA.
______
Designed for undergraduates wanting to continue substantial projects of own choice, under faculty supervision, in mechanical engineering. Work may be of experimental, theoretical, or design nature. Projects may be arranged individually in most fields of department interest, i.e., in mechanics, design and manufacturing, controls and robotics, thermal science and energy engineering, bioengineering, ocean engineering and nanotechnology. 2.993 is letter-graded; 2.994 is P/D/F.
Consult A. E. Hosoi
2.993: No textbook information available
2.994: No textbook information available

2.995 Advanced Topics in Mechanical Engineering
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
URL: http://www-mtl.mit.edu/Courses/6.095
TBA.
______
Assigned reading and problems or research in distinct areas, either theoretical or experimental, or design. Arranged on individual basis with instructor in the following areas: mechanics and materials, thermal and fluid sciences, systems and design, biomedical engineering, and ocean engineering. Can be repeated for credit only for completely different subject matter.
Consult R. Abeyaratne
No textbook information available

2.996-2.998 Advanced Topics in Mechanical Engineering
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
2.996: TBA.
2.997: TBA.
2.998: Lecture: TR11.30-1 (N51-350) Recitation: R1-2.30 (N51-350)
______
Assigned reading and problems or research in distinct areas, either theoretical or experimental, or design. Arranged on individual basis with instructor in the following areas: mechanics and materials, thermal and fluid sciences, systems and design, biomedical engineering, and ocean engineering. Can be repeated for credit only for completely different subject matter.
Consult R. Abeyaratne
2.996: No textbook information available
2.997: No textbook information available
2.998: No textbook information available

2.S790-2.S792 Graduate Special Subject in Bioengineering
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Advanced lecture, seminar or laboratory course consisting of material in the broadly-defined field of bioengineering not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Consult R. Kamm

2.S97 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

2.S971 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

2.S972 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (Fall) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
Lecture: F2-4 (3-370)
______
No textbook information available

2.S973 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (Fall) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
Lecture: T1-2.30 (E40-160)
______
No textbook information available

2.S974 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
______
Lecture, seminar or laboratory course consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter. 2.S972-2.S974 are graded P/D/F.
Consult A. E. Hosoi

2.S980 Graduate Special Subject in Mechanical Engineering
______

Graduate (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______

2.S981 Graduate Special Subject in Mechanical Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
Subject Cancelled Subject Cancelled
______

2.S982 Graduate Special Subject in Mechanical Engineering
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
Subject Cancelled Subject Cancelled
______

2.S992 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
Subject Cancelled Subject Cancelled
______

2.S993 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (Fall) Can be repeated for credit
Prereq: None
Units arranged
Lecture: TR11-12.30 (1-132) Lab: R2.30-4.30 (1-115)
______
No required or recommended textbooks

2.S994 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
Subject Cancelled Subject Cancelled
______

2.S995 Undergraduate Special Subject in Mechanical Engineering
______

Undergrad (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
Subject Cancelled Subject Cancelled
______

2.S996 Graduate Special Subject in Mechanical Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
Subject Cancelled Subject Cancelled
______

2.S997 Graduate Special Subject in Mechanical Engineering
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: MW11-12.30 (1-273) Recitation: R3 (1-134)
______
No textbook information available

2.S998 Graduate Special Subject in Mechanical Engineering
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: TR1-2.30 (1-375)
______
No required or recommended textbooks

2.S999 Graduate Special Subject in Mechanical Engineering
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: TR2.30-5 (NE45-202)
______
Advanced lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter. 2.S980 and 2.S996 are graded P/D/F.
Consult R. Abeyaratne
No textbook information available

Thesis, Research and Practice

2.978 Instruction in Teaching Engineering
______

Graduate (Fall)
(Subject meets with1.95[J],5.95[J],7.59[J],8.395[J],18.094[J])
Prereq: Permission of instructor
Units arranged [P/D/F]
Lecture: R9-11 (4-149)
______
Participatory seminar focuses on the knowledge and skills necessary for teaching engineering in higher education. Topics include research on learning; course development; promoting active learning, problemsolving, and critical thinking in students; communicating with a diverse student body; using educational technology to further learning; lecturing; creating effective tests and assignments; and assessment and evaluation. Field-work teaching various subjects in the Mechanical Engineering department will complement classroom discussions.
J. Rankin
No textbook information available

2.979 Undergraduate Teaching
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
For students participating in departmentally approved undergraduate teaching programs. Students assist faculty in the design and execution of the curriculum and actively participate in the instruction and monitoring of the class participants. Students prepare subject materials, lead discussion groups, and review progress. Credit is arranged on a subject-by-subject basis and is reviewed by the department.
A. E. Hosoi
No textbook information available

2.999 Engineer's Degree Thesis Proposal Preparation
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
For students who must do additional work to convert an SM thesis to an ME thesis, or for students who write an ME thesis after having received an SM degree.
R. Abeyaratne, M. S. Triantafyllou
No textbook information available

2.EPE UPOP Engineering Practice Experience
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.EPE,2.EPE,3.EPE,6.EPE,10.EPE,16.EPE,22.EPE)
Prereq: 2.EPW or permission of instructor
Units: 0-0-1 [P/D/F]
TBA.
______
Provides sophomores with guided practice in finding opportunities and excelling in the world of practice. Building on the skills and relationships acquired in the Engineering Practice Workshop, students receive coaching to articulate goals, invoke the UPOP network of mentors and employers, identify and pursue opportunities and negotiate terms of their summer assignment. Students complete a 10-12 week internship, which includes filing three progress reports, conducting one informational interview, and possibly hosting a site visit by MIT staff. Returning to campus as juniors, UPOP students take part in reflective exercises that aid assimilation of learning objectives and reinforce the cognitive link between all aspects of the UPOP experience and disciplinary fields of study. Sequence begins in the spring of sophomore year and ends in the fall of junior year.
Staff
No textbook information available

2.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No textbook information available

2.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of advisor
Units arranged
TBA.
______
Program of research leading to the writing of an SM, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member.
Consult R. Abeyaratne
Textbooks arranged individually

2.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Individual self-motivated study, research, or design project under faculty supervision. Departmental program requirement: minimum of 6 units. Instruction and practice in written communication provided.
Consult A. E. Hosoi
Textbooks arranged individually

2.UR Undergraduate Research in Mechanical Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually

2.URG Undergraduate Research in Mechanical Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Individual study, research, or laboratory investigations under faculty supervision, including individual participation in an ongoing research project. See projects listing in Undergraduate Office, 1-110, for guidance.
Consult N. Fang, K. Kamrin
Textbooks arranged individually


left arrow|2.000-2.199|2.20-2.7999|2.80-2.999 plus Thesis, UROP, UPOP|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 3: Materials Science and Engineering
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Course 3: Materials Science and Engineering
Fall 2016


3.003 Principles of Engineering Practice
______

Undergrad (Spring)
(Subject meets with3.004)
Prereq: Physics I (GIR), Calculus I (GIR)
Units: 1-2-6
URL: http://web.mit.edu/3.003/www/
______
Introduces students to the interdisciplinary nature of 21st-century engineering projects with three threads of learning: a technical toolkit, a social science toolkit, and a methodology for problem-based learning. Students encounter the social, political, economic, and technological challenges of engineering practice by participating in actual engineering projects involving public transportation and information infrastructure with faculty and industry. Student teams create prototypes and mixed media reports with exercises in project planning, analysis, design, optimization, demonstration, reporting and team building. Preference to freshmen.
L. Kimerling

3.004 Principles of Engineering Practice
______

Undergrad (Spring)
(Subject meets with3.003)
Prereq: Physics I (GIR),Calculus I (GIR)
Units: 3-3-6
______
Introduces students to the interdisciplinary nature of 21st-century engineering projects with three threads of learning: a technical toolkit, a social science toolkit, and a methodology for problem-based learning. Students encounter the social, political, economic and technological challenges of engineering practice via case studies and participation in engineering projects. Includes a six-stage term project in which student teams develop solutions through exercises in project planning, analysis, design, optimization, demonstration, reporting, and team building.
L. Kimerling

3.005 Passion Projects: Living in a Material World
______

Undergrad (Spring)
Prereq: None
Units: 1-2-6
______
Project-based seminar in which students formulate and answer questions about a material or object that interests and inspires them. Uses cutting-edge equipment to characterize the materials' structure in order to understand its role and functionality. Analyzes the lifecycle of the material to better understand the full use case. Culminates in the creation of a website, video, and final presentation in which students share the results of their research. Preference to freshmen; limited to 15.
K. Van Vliet

3.012 Fundamentals of Materials Science and Engineering
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: None.Coreq: 18.03, 18.034, or 3.016
Units: 5-0-10
Lecture: MWF1-3 (4-370) Recitation: TR1 (4-265) or TR2 (4-265) +final
______
Describes the fundamentals of structure and energetics that underpin materials science. Presents thermodynamic concepts and the laws governing equilibrium properties, and the connections between thermodynamic concepts and materials phenomena, such as phase transformations, multiphase equilibria, and chemical reactions. Introduces computerized thermodynamics. Structure of noncrystalline, crystalline, and liquid-crystalline states. Symmetry and tensor properties of materials. Point, line, and surface imperfections in materials. Diffraction and structure determination.
S. Gradečak, R. Jaramillo
Textbooks (Fall 2016)

3.014 Materials Laboratory
______

Undergrad (Fall) Institute Lab
Prereq: None
Units: 1-4-7
Lab: MWF1-5 (8-107) Recitation: TR1 (4-265) or TR2 (4-265) +final
______
Experimental exploration of the connections between structure, properties, processing, and performance of materials. Hands-on experience with materials characterization techniques and instrumentation. Covers methodology of technical communication (written and oral) with a view to integrate experimental design, execution, and analysis. Concurrent enrollment in 3.012 and 3.014 strongly recommended.
L. Kimerling, D. Sadoway
No required or recommended textbooks

3.016 Computational Methods for Materials Scientists and Engineers
______

Undergrad (Fall)
Prereq: Calculus II (GIR)
Units: 3-1-8
URL: http://pruffle.mit.edu/3.016
Thurs recitation meets in 37-. Lecture: MWF4 (W31-301) Lab: R EVE (7.30 PM) (W31-301) Recitation: TBA or R2 (W31-301)
______
Computational and analytical techniques necessary for materials science and engineering topics, such as material structure, symmetry, and thermodynamics, materials response to applied fields, mechanics and physics of solids and soft materials. Presents mathematical concepts and materials-related problem solving skills alongside symbolic programming techniques. Symbolic algebraic computational methods, programming, and visualization techniques; topics include linear algebra, quadratic forms, tensor operations, symmetry operations, calculus of several variables, eigensystems, systems of ordinary and partial differential equations, beam theory, resonance phenomena, special functions, numerical solutions, statistical analysis, Fourier analysis, and random walks.
W. C. Carter
No required or recommended textbooks

3.017 Modelling, Problem Solving, Computing, and Visualization
______

Undergrad (Spring)
Prereq: 3.016, 6.0001, 16.66, or 12.010; 3.014, 3.022, or 3.024; or permission of instructor
Units: 2-2-8
______
Covers development and design of models for materials processes and structure-property relations. Emphasizes techniques for solving equations from models or simulating their behavior. Assesses methods for visualizing solutions and aesthetics of the graphical presentation of results. Topics include symmetry and structure, classical and statistical thermodynamics, solid state physics, mechanics, phase transformations and kinetics, statistics and presentation of data.
W. C. Carter

3.021 Introduction to Modeling and Simulation
______

Undergrad (Spring) Rest Elec in Sci & Tech
Engineering School-Wide Elective Subject.
(Offered under:1.021,3.021,10.333,22.00)
Prereq: 18.03, 3.016, or permission of instructor
Units: 4-0-8
______
Basic concepts of computer modeling and simulation in science and engineering. Uses techniques and software for simulation, data analysis and visualization. Continuum, mesoscale, atomistic and quantum methods used to study fundamental and applied problems in physics, chemistry, materials science, mechanics, engineering, and biology. Examples drawn from the disciplines above are used to understand or characterize complex structures and materials, and complement experimental observations.
M. Buehler, R. Taylor

3.022 Microstructural Evolution in Materials
______

Undergrad (Spring)
Prereq: 3.012
Units: 3-3-6
______
Covers microstructures, defects, and structural evolution in all classes of materials. Topics include solution kinetics, interface stability, dislocations and point defects, diffusion, surface energetics, grains and grain boundaries, grain growth, nucleation and precipitation, and electrochemical reactions. Lectures illustrate a range of examples and applications based on metals, ceramics, electronic materials, polymers, and biomedical materials. Explores the evolution of microstructure through experiments involving optical and electron microscopy, calorimetry, electrochemical characterization, surface roughness measurements, and other characterization methods. Investigates structural transitions and structure-property relationships through practical materials examples.
Y. Chiang, G. Beach, J. Hu

3.024 Electronic, Optical and Magnetic Properties of Materials
______

Undergrad (Spring)
Prereq: 3.012
Units: 3-3-6
______
Uses fundamental principles of quantum mechanics, solid state physics, electricity and magnetism to describe how the electronic, optical and magnetic properties of materials originate. Illustrates how these properties can be designed for particular applications, such as diodes, solar cells, optical fibers, and magnetic data storage. Involves experimentation using spectroscopy, resistivity, impedance and magnetometry measurements, behavior of light in waveguides, and other characterization methods. Uses practical examples to investigate structure-property relationships.
P. Anikeeva, G. Beach, J. Hu

3.032 Mechanical Behavior of Materials
______

Undergrad (Fall)
Prereq: Physics I (GIR); 3.016 or 18.03
Units: 3-1-8
Lecture is on-line. R class meets in 4-153. Lab: T9-1 (8-107) or R9-1 (8-107) Recitation: M1-2.30,RF1 (4-261)
______
Basic concepts of solid mechanics and mechanical behavior of materials: elasticity, stress-strain relationships, stress transformation, viscoelasticity, plasticity and fracture. Continuum behavior as well as atomistic explanations of the observed behavior are described. Examples from engineering as well as biomechanics. Lab experiments and demonstrations give hands-on experience of the physical concepts. Offers a combination of online and in-person instruction.
L. Gibson
Textbooks (Fall 2016)

3.034 Organic and Biomaterials Chemistry
______

Undergrad (Fall)
Prereq: 3.012
Units: 4-2-6
Lecture: MWF11 (4-153) Lab: T9-1 (8-107) or R9-1 (8-107) Recitation: T11 (8-119) or R11 (8-119)
______
Focuses on the chemistry and chemical structure-property relationships of soft synthetic and biologically derived materials. Topics include methods for preparing synthetic polymers by step and chain growth polymerizations; polymerization reaction kinetics; chemistry of proteins, nucleic acids, polysaccharides and lipids, and their incorporation into biomaterials and biosensors; enzymatic reactions and ligations; chemical modification and patterning of organic and inorganic surfaces using organosilane and self-assembled monolayer chemistries, radiation grafting, physisorption and microcontact printing; organic systems as templates for inorganic materials; sol gel syntheses, polymer precursor conversions, polymer vesicle naroreactors; chemical degradation of soft materials through readition, hydrolysis, and thermolysis; electroactive organic materials. Firsthand application of lecture topics through design-oriented experiments.
R. Macfarlane
No required or recommended textbooks

3.035 Problems in Materials Science and Engineering
______

Undergrad (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
3.035: TBA.
______
Staff
3.035: No textbook information available

3.036, 3.037 Problems in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
3.036: TBA.
3.037: TBA.
______
3.036: No textbook information available
3.037: No textbook information available

3.038, 3.039, 3.04 Problems in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
3.038: TBA.
3.039: TBA.
3.04: TBA.
______
For undergraduates desiring to carry on projects of their own choosing, which may be experimental, theoretical, or of a design nature. Also for undergraduate studies arranged by students or staff, which may consist of seminars, assigned reading, or laboratory projects. See UROP Coordinator for registration procedures.
Staff
3.038: No textbook information available
3.039: No textbook information available
3.04: No textbook information available

3.042 Materials Project Laboratory
______

Undergrad (Fall, Spring)
Prereq: 3.014, 3.032, or 3.044
Units: 1-6-5
Lecture: R1 (4-145) Lab: TR2-5 (4-131B)
______
Student project teams design and fabricate a working prototype using materials processing technologies (e.g. solid works 3-D design software, computer numerical controlled mill, injection molding, thermoforming, investment casting, powder processing, three-dimensional printing, physical vapor deposition) appropriate for the materials and device of interest. Goals include using MSE fundamentals in a practical application; understanding trade-offs between design, processing, and performance and cost; and fabrication of a deliverable prototype. Emphasis on teamwork, project management, communications and computer skills, with extensive hands-on work using student and MIT laboratory shops. Teams document their progress and final results by means of written and oral communication. Limited to 25.
M. Tarkanian
No required or recommended textbooks

3.044 Materials Processing
______

Undergrad (Spring)
Prereq: 3.012, 3.022
Units: 4-0-8
______
Introduction to materials processing science, with emphasis on heat transfer, chemical diffusion, and fluid flow. Uses an engineering approach to analyze industrial-scale processes, with the goal of identifying and understanding physical limitations on scale and speed. Covers materials of all classes, including metals, polymers, electronic materials, and ceramics. Considers specific processes, such as melt-processing of metals and polymers, deposition technologies (liquid, vapor, and vacuum), colloid and slurry processing, viscous shape forming, and powder consolidation.
E. Olivetti

3.046 Thermodynamics of Materials
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: 3.012 or permission of instructor
Units: 4-0-8
______
Explores equilibrium thermodynamics through its application to topics in materials science and engineering. Begins with a fast-paced review of introductory classical and statistical thermodynamics. Students select additional topics to cover; examples include batteries and fuel cells, solar photovoltaics, magnetic information storage, extractive metallurgy, corrosion, thin solid films, and computerized thermodynamics.
R. Jaramillo

3.048 Advanced Materials Processing
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 3.022, 3.044
Units: 3-0-9
______
Fundamentals of materials processing. Building engineering structures from the atomic- and nano-scales to macroscopic levels. Case studies illustrating application of processing science to creation of modern metallic, ceramic, polymeric and biomaterials devices and components.
Staff

3.052 Nanomechanics of Materials and Biomaterials
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 3.032 or permission of instructor
Units: 3-0-9
______
Latest scientific developments and discoveries in the field of nanomechanics, i.e. the deformation of extremely tiny (10-9 meters) areas of synthetic and biological materials. Lectures include a description of normal and lateral forces at the atomic scale, atomistic aspects of adhesion, nanoindentation, molecular details of fracture, chemical force microscopy, elasticity of individual macromolecular chains, intermolecular interactions in polymers, dynamic force spectroscopy, biomolecular bond strength measurements, and molecular motors.
Staff

3.053[J] Molecular, Cellular, and Tissue Biomechanics
______

Undergrad (Spring)
(Same subject as2.797[J],6.024[J],20.310[J])
Prereq: 2.370 or 2.772J; 18.03 or 3.016; Biology (GIR)
Units: 4-0-8
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, A. J. Grodzinsky, K. Van Vliet

3.054 Cellular Solids: Structure, Properties, Applications
______

Undergrad (Fall)
(Subject meets with3.36)
Prereq: 3.032
Units: 2-0-10
Lecture: T9.30-11 (2-136)
______
Discusses processing and structure of cellular solids as they are created from polymers, metals, ceramics, glasses, and composites; derivation of models for the mechanical properties of honeycombs and foams; and how unique properties of honeycombs and foams are exploited in applications such as lightweight structural panels, energy absorption devices, and thermal insulation. Covers applications of cellular solids in medicine, such as increased fracture risk due to trabecular bone loss in patients with osteoporosis, the development of metal foam coatings for orthopedic implants, and designing porous scaffolds for tissue engineering that mimic the extracellular matrix. Includes modelling of cellular materials applied to natural materials and biomimicking. Offers a combination of online and in-person instruction. Students taking graduate version complete additional assignments.
L. Gibson
Textbooks (Fall 2016)

3.055[J] Biomaterials Science and Engineering
______

Undergrad (Fall)
(Same subject as20.363[J])
(Subject meets with3.963[J],20.463[J])
Prereq: 3.034, 20.110, or permission of instructor
Units: 3-0-9
Lecture: MW11-12.30 (56-614)
______
Covers, at a molecular scale, the analysis and design of materials used in contact with biological systems, and biomimetic strategies aimed at creating new materials based on principles found in biology. Topics include molecular interaction between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of materials science to problems in tissue engineering, drug delivery, vaccines, and cell-guiding surfaces. Students taking graduate version complete additional assignments.
D. Irvine, K. Ribbeck
No textbook information available

3.063 Polymer Physics
______

Undergrad (Spring)
(Subject meets with3.942)
Prereq: 3.012
Units: 4-0-8
______
The mechanical, optical, electrical, and transport properties of polymers and other types of "soft matter" are presented with respect to the underlying physics and physical chemistry of polymers and colloids in solution, and solid states. Topics include how enthalpy and entropy determine conformation, molecular dimensions and packing of polymer chains and colloids and supramolecular materials. Examination of the structure of glassy, crystalline, and rubbery elastic states of polymers; thermodynamics of solutions, blends, crystallization; liquid crystallinity, microphase separation, and self-assembled organic-inorganic nanocomposites. Case studies of relationships between structure and function in technologically important polymeric systems. Students taking graduate version complete additional assignments.
A. Alexander-Katz

3.064 Polymer Engineering
______

Undergrad (Fall)
Prereq: 3.032, 3.044
Units: 3-0-9
URL: http://web.mit.edu/course/3/3.064/www/
Lecture: MWF12 (4-145)
______
Overview of polymer material science and engineering. Treatment of physical and chemical properties, mechanical characterization, processing, and their control through inspired polymer material design.
N. Holten-Andersen
No textbook information available

3.07 Introduction to Ceramics
______

Undergrad (Fall)
Prereq: 3.012
Units: 3-0-9
Lecture: MW2.30-4 (8-119)
______
Discusses structure-property relationships in ceramic materials. Includes hierarchy of structures from the atomic to microstructural levels. Defects and transport, solid-state electrochemical processes, phase equilibria, fracture and phase transformations are discussed in the context of controlling properties for various applications of ceramics. Numerous examples from current technology.
Y. Chiang
No required or recommended textbooks

3.071 Amorphous Materials
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 3.024
Units: 3-0-9
______
Discusses the fundamental material science behind amorphous solids (non-crystalline materials). Covers formation of amorphous solids; amorphous structures and their electrical and optical properties; and characterization methods and technical applications.
J. Hu

3.072 Symmetry, Structure and Tensor Properties of Materials
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with3.60)
Prereq: 3.016 or 18.03
Units: 4-0-8
Subject Cancelled Subject Cancelled
______
Studies the underlying structures of materials and deepens understanding of the relationship between the properties of materials and their structures. Topics include lattices, point groups, and space groups in both two and three dimensions; the use of symmetry in the tensor representation of crystal properties; and the relationship between crystalline structure and properties, including transport properties, piezoelectricity, and elasticity. Students taking graduate version complete additional assignments.
R. Taylor, E. Fitzgerald

3.074 Imaging of Materials
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with3.34)
Prereq: 3.024
Units: 3-0-9
______
Principles and applications of imaging techniques for materials characterization including transmission and scanning electron microscopy and scanning probe microscopy. Topics include electron diffraction; image formation in transmission and scanning electron microscopy; diffraction and phase contrast; imaging of crystals and crystal imperfections; review of the most recent advances in electron microscopy for bio- and nanosciences; analysis of chemical composition and electronic structure at the atomic scale. Lectures, real-case studies and computer simulations.
S. Gradečak

3.080 Strategic Materials Selection
______

Undergrad (Spring)
Prereq: 3.012, 3.014, or permission of instructor
Units: 3-0-9
______
Provides a survey of methods for evaluating choice of material and explores the implications of that choice. Topics include manufacturing economics and utility analysis. Students carry out a group project selecting materials technology options based on economic characteristics.
R. Kirchain

3.081 Industrial Ecology of Materials
______

Undergrad (Fall)
(Subject meets with3.560)
Prereq: 3.012, 3.014, or permission of instructor
Units: 3-0-9
URL: http://www-dmse.mit.edu/courses/3.081/
Lecture: MW2.30-4 (8-205)
______
Covers quantitative techniques to address principles of substitution, dematerialization, and waste mining implementation in materials systems. Includes life-cycle and materials flow analysis of the impacts of materials extraction; processing; use; and recycling for materials, products, and services. Student teams undertake a case study regarding materials and technology selection using the latest methods of analysis and computer-based models of materials process. Students taking graduate version complete additional assignments.
E. Olivetti
No required or recommended textbooks

3.086 Innovation and Commercialization of Materials Technology
______

Undergrad (Spring)
(Subject meets with3.207)
Prereq: None
Units: 4-0-8
______
Covers the fundamental process of innovation through its implications on organizations and innovation ecosystems. Emphasizes historical and modern examples of innovation in materials and devices. Discusses the final implications for innovation ecosystems.
E. Fitzgerald

3.091 Introduction to Solid-State Chemistry
______

Undergrad (Fall, Spring) Chemistry
(Subject meets withES.3091)
Prereq: None
Units: 5-0-7
Credit cannot also be received for5.111,5.112,CC.5111,ES.5111,ES.5112
Lecture: MWF11 (10-250) Recitation: TR9 (36-155) or TR10 (36-155, 13-5101, 13-4101) or TR11 (1-242, 36-155, 13-5101, 13-4101) or TR12 (36-155, 13-5101, 13-3101) or TR2 (13-1143, 26-322, 26-302, 13-3101, 36-144) or TR3 (13-4101) or TR4 (13-4101) +final
______
Basic principles of chemistry and their application to engineering systems. The relationship between electronic structure, chemical bonding, and atomic order. Characterization of atomic arrangements in crystalline and amorphous solids: metals, ceramics, semiconductors, and polymers. Topical coverage of organic chemistry, solution chemistry, acid-base equilibria, electrochemistry, biochemistry, chemical kinetics, diffusion, and phase diagrams. Examples from industrial practice (including the environmental impact of chemical processes), from energy generation and storage (e.g., batteries and fuel cells), and from emerging technologies (e.g., photonic and biomedical devices).
Fall:J. Grossman
Spring:N. Holten-Andersen, R. Macfarlane
Textbooks (Fall 2016)

3.094 Materials in Human Experience
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 2-3-4
______
Examines the ways in which people in ancient and contemporary societies have selected, evaluated, and used materials of nature, transforming them to objects of material culture. Some examples: glass in ancient Egypt and Rome; sounds and colors of powerful metals in Mesoamerica; cloth and fiber technologies in the Inca empire. Explores ideological and aesthetic criteria often influential in materials development. Laboratory/workshop sessions provide hands-on experience with materials discussed in class. Subject complements 3.091. Enrollment may be limited.
H. N. Lechtman

3.14 Physical Metallurgy
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with3.40[J],22.71[J])
Prereq: 3.022, 3.032
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Focuses on the links between the processing, structure, and properties of metals and alloys. First, the physical bases for strength, stiffness, and ductility are discussed with reference to crystallography, defects, and microstructure. Second, phase transformations and microstructural evolution are studied in the context of alloy thermodynamics and kinetics. Together, these components comprise the modern paradigm for designing metallic microstructures for optimized properties. Concludes with a focus on processing/microstructure/property relationships in structural engineering alloys, particularly steels and aluminum alloys. Students taking the graduate version explore the subject in greater depth.
C. Tasan

3.15 Electrical, Optical, and Magnetic Materials and Devices
______

Undergrad (Spring)
Prereq: 3.024
Units: 4-0-8
______
Explores the relationships between the performance of electrical, optical, and magnetic devices and the microstructural characteristics of the materials from which they are constructed. Features a device-motivated approach that places strong emphasis on emerging technologies. Applications include diodes, transistors, photodetectors, solar cells (photovoltaics), displays, light emitting diodes, lasers, optical fibers and optical communications, photonic devices, magnetic data storage and spintronics.
C. A. Ross

3.152 Magnetic Materials
______

Undergrad (Fall)
(Subject meets with3.45)
Prereq: 3.024
Units: 3-0-9
Lecture: TR1-2.30 (4-149)
______
Topics include origin of magnetism in materials, magnetic domains and domain walls, magnetostatics, magnetic anisotropy, antiferro- and ferrimagnetism, magnetism in thin films and nanoparticles, magnetotransport phenomena, and magnetic characterization. Discusses a range of applications, including magnetic recording, spin-valves, and tunnel-junction sensors. Assignments include problem sets and a term paper on a magnetic device or technology. Students taking graduate version complete additional assignments.
C. Ross
Textbooks (Fall 2016)

3.153 Nanoscale Materials
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 3.024
Units: 4-0-8
______
Builds on concepts from quantum mechanics and electromagnetics to develop an understanding of the properties of materials on the nanoscale. Illustrates the promise and challenges facing the field through case studies and the survey of fabrication methods.
Y. Fink

3.154[J] Materials Performance in Extreme Environments
______

Not offered academic year 2016-2017Undergrad (Spring)
(Same subject as22.054[J])
Prereq: 3.032, 3.044
Units: 3-2-7
______
Studies the behavior of materials in extreme environments typical of those in which advanced energy systems (including fossil, nuclear, solar, fuel cells, and battery) operate. Takes both a science and engineering approach to understanding how current materials interact with their environment under extreme conditions. Explores the role of modeling and simulation in understanding material behavior and the design of new materials. Focuses on energy and transportation related systems.
R. Ballinger

3.155[J] Micro/Nano Processing Technology
______

Undergrad (Fall)
(Same subject as6.152[J])
Prereq: Permission of instructor
Units: 3-4-5
Lecture: MW2.30-4 (32-124)
______
Introduces the theory and technology of micro/nano fabrication. Lectures and laboratory sessions on basic processing techniques such as vacuum processes, lithography, diffusion, oxidation, and pattern transfer. Students fabricate MOS capacitors, nanomechanical cantilevers, and microfluidic mixers. Emphasis on the interrelationships between material properties and processing, device structure, and the electrical, mechanical, optical, chemical or biological behavior of devices. Provides background for thesis work in micro/nano fabrication. Students engage in extensive written and oral communication exercises.
L. F. Velasquez-Garcia, J. Michel
Textbooks (Fall 2016)

3.156 Photonic Materials and Devices
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with3.46)
Prereq: 3.016 or 18.03; 3.024
Units: 3-0-9
______
Optical materials design for semiconductors, dielectrics, organic and nanostructured materials. Ray optics, electromagnetic optics and guided wave optics. Physics of light-matter interactions. Device design principles: LEDs, lasers, photodetectors, solar cells, modulators, fiber and waveguide interconnects, optical filters, and photonic crystals. Device processing: crystal growth, substrate engineering, thin film deposition, etching and process integration for dielectric, silicon and compound semiconductor materials. Micro- and nanophotonic systems. Organic, nanostructured and biological optoelectronics. Assignments include three design projects that emphasize materials, devices and systems applications. Students taking graduate version complete additional assignments.
P. Anikeeva

3.18 Materials Science and Engineering of Clean Energy
______

Undergrad (Spring)
(Subject meets with3.70)
Prereq: 3.022, 3.024
Units: 3-0-9
______
Develops the materials principles, limitations, and challenges of clean energy technologies, including solar, energy storage, thermoelectrics, fuel cells, and novel fuels. Draws correlations between the limitations and challenges related to key figures of merit and the basic underlying thermodynamic, structural, transport, and physical principles, as well as to the means for fabricating devices exhibiting optimum operating efficiencies and extended life at reasonable cost. Students taking graduate version complete additional assignments.
H. Tuller, K. Van Vliet

3.19 Sustainable Chemical Metallurgy
______

Undergrad (Spring)
(Subject meets with3.50)
Prereq: 3.022
Units: 3-0-9
______
Covers principles of metal extraction processes. Provides a direct application of the fundamentals of thermodynamics and kinetics to the industrial production of metals from their ores, e.g., iron, aluminum, or reactive metals and silicon. Discusses the corresponding economics and global challenges. Addresses advanced techniques for sustainable metal extraction, particularly with respect to greenhouse gas emissions. Students taking graduate version complete additional assignments.
A. Allanore

3.20 Materials at Equilibrium
______

Graduate (Fall)
Prereq: 3.012, 3.014, 3.022, 3.024, 3.034, 3.042; or permission of instructor
Units: 5-0-10
Lecture: MW9.30-11,F10 (37-212) Recitation: R3 (13-3101) or F11 (13-5101) or F12 (13-5101) +final
______
Laws of thermodynamics: general formulation and applications to mechanical, electromagnetic and electrochemical systems, solutions, and phase diagrams. Computation of phase diagrams. Statistical thermodynamics and relation between microscopic and macroscopic properties, including ensembles, gases, crystal lattices, phase transitions. Applications to phase stability and properties of mixtures. Representations of chemical equilibria. Interfaces.
A. Allanore; A. Alexander-Katz
Textbooks (Fall 2016)

3.207 Innovation and Commercialization
______

Graduate (Spring)
(Subject meets with3.086)
Prereq: None
Units: 4-0-8
______
Explores in depth projects on a particular materials-based technology. Investigates the science and technology of materials advances and their strategic value, explore potential applications for fundamental advances, and determine intellectual property related to the materials technology and applications. Students map progress with presentations, and are expected to create an end-of-term document enveloping technology, intellectual property, applications, and potential commercialization. Lectures cover aspects of technology, innovation, entrepreneurship, intellectual property, and commercialization of fundamental technologies.
E. Fitzgerald

3.21 Kinetic Processes in Materials
______

Graduate (Spring)
Prereq: 3.012, 3.022, 3.044, or permission of instructor
Units: 5-0-10
______
Unified treatment of phenomenological and atomistic kinetic processes in materials. Provides the foundation for the advanced understanding of processing, microstructural evolution, and behavior for a broad spectrum of materials. Topics include irreversible thermodynamics; rate and transition state theory, diffusion; nucleation and phase transitions; continuous phase transitions; grain growth and coarsening; capillarity driven morphological evolution; and interface stability during phase transitions.
C. Thompson

3.22 Mechanical Behavior of Materials
______

Graduate (Spring)
Prereq: 3.032 or permission of instructor
Units: 4-0-8
URL: http://web.mit.edu/3.22/www/
______
Explores how the macroscale mechanical behavior of materials originates from fundamental, microscale mechanisms of elastic and inelastic deformation. Topics include: elasticity, viscoelasticity, plasticity, creep, fracture, and fatigue. Case studies and examples are drawn from a variety of material classes: metals, ceramics, polymers, thin films, composites, and cellular materials.
C. Tasan

3.23 Electrical, Optical, and Magnetic Properties of Materials
______

Graduate (Fall)
Prereq: 8.03, 18.03
Units: 4-0-8
Lecture: TR10-11.30 (4-231) Recitation: W2 (13-4101) or W3 (13-4101) +final
______
Origin of electrical, magnetic and optical properties of materials. Focus on the acquisition of quantum mechanical tools. Analysis of the properties of materials. Presentation of the postulates of quantum mechanics. Examination of the hydrogen atom, simple molecules and bonds, and the behavior of electrons in solids and energy bands. Introduction of the variation principle as a method for the calculation of wavefunctions. Investigation of how and why materials respond to different electrical, magnetic and electromagnetic fields and probes. Study of the conductivity, dielectric function, and magnetic permeability in metals, semiconductors, and insulators. Survey of common devices such as transistors, magnetic storage media, optical fibers.
G. Beach
Textbooks (Fall 2016)

3.31[J] Radiation Damage and Effects in Nuclear Materials
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as22.74[J])
Prereq: 22.14, 3.21, or permission of instructors
Units: 3-0-9
______
Studies the origins and effects of radiation damage in structural materials for nuclear applications. Radiation damage topics include formation of point defects, defect diffusion, defect reaction kinetics and accumulation, and differences in defect microstructures due to the type of radiation (ion, proton, neutron). Radiation effects topics include detrimental changes to mechanical properties, phase stability, corrosion properties, and differences in fission and fusion systems. Term project required.
M. Short

3.320 Atomistic Computer Modeling of Materials
______

Graduate (Spring)
Prereq: 3.022, 3.20, 3.23 or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/3.320/www/
______
Theory and application of atomistic computer simulations to model, understand, and predict the properties of real materials. Energy models: from classical potentials to first-principles approaches. Density-functional theory and the total-energy pseudopotential method. Errors and accuracy of quantitative predictions. Thermodynamic ensembles: Monte Carlo sampling and molecular dynamics simulations. Free energies and phase transitions. Fluctations and transport properties. Coarse-graining approaches and mesoscale models.
B. Kozinsky

3.33[J] Defects in Materials
______

Graduate (Fall)
(Same subject as22.73[J])
Prereq: 3.21, 3.22
Units: 3-0-9
Lecture: F11-12.30 (24-121) Recitation: F EVE (4.30-6 PM) (24-115) +final
______
Examines point, line, and planar defects in structural and functional materials. Relates their properties to transport, radiation response, phase transformations, semiconductor device performance and quantum information processing. Focuses on atomic and electronic structures of defects in crystals, with special attention to optical properties, dislocation dynamics, fracture, and charged defects population and diffusion. Examples also drawn from other systems, e.g., disclinations in liquid crystals, domain walls in ferromagnets, shear bands in metallic glass, etc.
J. Li
No textbook information available

3.34 Imaging of Materials
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with3.074)
Prereq: 3.23 or permission of instructor
Units: 3-0-9
URL: http://www-dmse.mit.edu/courses/3.34/3.34.html
______
Principles and applications of imaging techniques for materials characterization including transmission and scanning electron microscopy and scanning probe microscopy. Topics include electron diffraction; image formation in transmission and scanning electron microscopy; diffraction and phase contrast; imaging of crystals and crystal imperfections; review of the most recent advances in electron microscopy for bio- and nanosciences; analysis of chemical composition and electronic structure at the atomic scale. Lectures, real-case studies and computer simulations. Graduate students complete additional assignments.
S. Gradečak

3.35 Fracture and Fatigue
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 3.032, permission of instructor
Units: 3-0-9
______
Linear elastic and elastic-plastic fracture mechanics. Theory and asymptotic analysis of crack-tip fields. Experimental methods. Microstructural effects on fracture in metals, ceramics, polymers, thin films, biological materials, and composites. Toughening mechanisms. Crack growth resistance and creep fracture. Interface fracture mechanics. Fatigue damage and dislocation substructures in single crystals. Stress- and strain-life approach to fatigue. Fatigue crack growth models and mechanisms. Variable amplitude fatigue. Corrosion fatigue. Case studies of fracture and fatigue in structural, bioimplant, and microelectronic components. Limited to 10.
M. Dao

3.36 Cellular Solids: Structure, Properties, Applications
______

Graduate (Fall)
(Subject meets with3.054)
Prereq: 3.032 or permission of instructor
Units: 3-0-9
Lecture: TR9.30-11 (2-136)
______
Discusses processing and structure of cellular solids as they are created from polymers, metals, ceramics, glasses, and composites; derivation of models for the mechanical properties of honeycombs and foams; and how unique properties of honeycombs and foams are exploited in applications such as lightweight structural panels, energy absorption devices, and thermal insulation. Covers applications of cellular solids in medicine, such as increased fracture risk due to trabecular bone loss in patients with osteoporosis, the development of metal foam coatings for orthopedic implants, and designing porous scaffolds for tissue engineering that mimic the extracellular matrix. Includes modelling of cellular materials applied to natural materials and biomimicking. Students taking graduate version complete additional assignments.
L. Gibson
Textbooks (Fall 2016)

3.371[J] Selection and Processing of Structural Materials
______

Graduate (Fall, Spring, Summer) Can be repeated for credit; partial term
(Same subject as2.821[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: MWF9 (4-145) Recitation: TR9 (4-145)
______
Discusses selection design and processing for structural materials, including casting, forging, rolling, drawing, extrusion, powder consolidation, welding, brazing, soldering, wear, corrosion, non-destructive testing and fracture. Emphasizes the underlying science of a given process rather than a detailed description of the technique or equipment. Presented in modules; repeatable for credit one time with permission of instructor, provided three different modules are selected the second term.
T. Eagar
No required or recommended textbooks
______
Summer 2016 Description for Selection and Processing of Structural Materials
(Same subject as 2.821J) (Subject meets with 3.S171)
Prereq:Permission of instructor
Units: 3-0-9
Can be repeated for credit

Discusses selection design and processing for structural materials, including casting, forging, rolling, drawing, extrusion, powder consolidation, welding, brazing, soldering, wear, corrosion, non-destructive testing and fracture. Emphasizes the underlying science of a given process rather than a detailed description of the technique or equipment. Presented in modules; repeatable for credit one time with permission of instructor, provided three different modules are selected the second term.

T. Eager
Section: MTWThF 8:00 AM-10:00 AM Room 4-145 From 06-JUN-16 Thru 22-JUL-16

3.40[J] Modern Physical Metallurgy
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as22.71[J])
(Subject meets with3.14)
Prereq: 3.022, 3.032
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Examines how the presence of 1-, 2- and 3-D defects and second phases control the mechanical, electromagnetic and chemical behavior of metals and alloys. Considers point, line and interfacial defects in the context of structural transformations including annealing, spinodal decomposition, nucleation, growth, and particle coarsening. Concentrates on structure-function relationships, and in particular how grain size, interstitial and substitutional solid solutions, and second-phase particles impact mechanical and other properties Industrially relevant case studies illustrate lecture concepts. Students taking the graduate version explore the subject in greater depth.
C. Tasan

3.41 Colloids, Surfaces, Absorption, Capillarity, and Wetting Phenomena
______

Graduate (Spring)
Prereq: 3.20, 3.21
Units: 3-0-9
______
Integrates elements of physics and chemistry toward the study of material surfaces. Begins with classical colloid phenomena and the interaction between surfaces in different media. Discusses the mechanisms of surface charge generation as well as how dispersion forces are created and controlled. Continues with exploration of chemical absorption processes and surface design of inorganic and organic materials. Includes examples in which such surface design can be used to control critical properties of materials in applications. Addresses lastly how liquids interact with solids as viewed by capillarity and wetting phenomena. Studies how materials are used in processes and applications that are intended to control liquids, and how the surface chemistry and structure of those materials makes such applications possible.
M. Cima

3.42 Electronic Materials Design
______

Graduate (Fall)
Prereq: 3.23
Units: 3-0-9
Lecture: MW11-12.30 (3-333)
______
Extensive and intensive examination of structure-processing-property correlations for a wide range of materials including metals, semiconductors, dielectrics, and optical materials. Topics covered include defect equilibria; junction characteristics; photodiodes, light sources and displays; bipolar and field effect transistors; chemical, thermal and mechanical transducers; data storage. Emphasis on materials design in relation to device performance.
H. L. Tuller
Textbooks (Fall 2016)

3.43[J] Integrated Microelectronic Devices
______

Graduate (Fall)
(Same subject as6.720[J])
Prereq: 6.012 or 3.42
Units: 4-0-8
Lecture: MWRF10 (66-144) +final
______
Covers physics of microelectronic semiconductor devices for integrated circuit applications. Topics include semiconductor fundamentals, p-n junction, metal-oxide semiconductor structure, metal-semiconductor junction, MOS field-effect transistor, and bipolar junction transistor. Studies modern nanoscale devices, including electrostatic scaling, materials beyond Si, carrier transport from the diffusive to the ballistic regime. Emphasizes physical understanding of device operation through energy band diagrams and short-channel MOSFET device design. Includes device modeling exercises. Familiarity with MATLAB required.
D. A. Antoniadis, J. A. del Alamo, H. L. Tuller
No textbook information available

3.44 Materials Processing for Micro- and Nano-Systems
______

Graduate (Fall)
Prereq: 3.20, 3.21
Units: 3-0-9
Lecture: TR9.30-11 (4-153) +final
______
Processing of bulk, thin film, and nanoscale materials for applications in electronic, magnetic, electromechanical, and photonic devices and microsystems. Topics include growth of bulk, thin-film, nanoscale single crystals via vapor and liquid phase processes; formation, patterning and processing of thin films, with an emphasis on relationships among processing, structure, and properties; and processing of systems of nanoscale materials. Examples from materials processing for applications in high-performance integrated electronic circuits, micro-/nano-electromechanical devices and systems and integrated sensors.
C. V. Thompson
Textbooks (Fall 2016)

3.45 Magnetic Materials
______

Graduate (Fall)
(Subject meets with3.152)
Prereq: 3.23
Units: 3-0-9
Lecture: TR1-2.30 (4-149)
______
Foundation topics include magnetostatics, origin of magnetism in materials, magnetic domains and domain walls, magnetic anisotropy, reversible and irreversible magnetization processes; hard and soft magnetic materials and magnetic recording. Special topics are selected from magnetism at nanoscale (thin films, surfaces, particles); amorphous and nanocrystalline magnetic materials; electronic transport in ferromagnets including magnetoresistive, spin-valve and spin-tunnel junction sensors.
C. Ross
Textbooks (Fall 2016)

3.46 Photonic Materials and Devices
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with3.156)
Prereq: 3.23
Units: 3-0-9
______
Optical materials design for semiconductors, dielectrics and polymers. Ray optics, electromagnetic optics and guided wave optics. Physics of light-matter interactions. Device design principles: LEDs, lasers, photodetectors, modulators, fiber and waveguide interconnects, optical filters, and photonic crystals. Device processing: crystal growth, substrate engineering, thin film deposition, etching and process integration for dielectric, silicon and compound semiconductor materials. Microphotonic integrated circuits. Telecom/datacom systems. Assignments include three design projects that emphasize materials, devices and systems applications. Students taking graduate version complete additional assignments.
P. Anikeeva


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Produced: 29-SEP-2016 06:37 AMFall 2016 Course 3: Materials Science and Engineering
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Course 3: Materials Science and Engineering
Fall 2016


3.50 Sustainable Chemical Metallurgy
______

Graduate (Spring)
(Subject meets with3.19)
Prereq: 3.022 or permission of instructor
Units: 3-0-9
______
Covers principles of metal extraction processes. Provides a direct application of the fundamentals of thermodynamics and kinetics to the industrial production of metals from their ores, e.g. iron, aluminum, or reactive metals and silicon. Discusses the corresponding economics and global challenges. Addresses advanced techniques for sustainable metal extraction, particularly with respect to greenhouse gas emissions. Students taking graduate version complete additional assignments.
A. Allanore

3.53 Electrochemical Processing of Materials
______

Graduate (Spring); partial term
Prereq: 3.044
Units: 3-0-6
______
Thermodynamic and transport properties of aqueous and nonaqueous electrolytes. The electrode/electrolyte interface. Kinetics of electrode processes. Electrochemical characterization: d.c. techniques (controlled potential, controlled current), a.c. techniques (voltametry and impedance spectroscopy). Applications: electrowinning, electrorefining, electroplating, and electrosynthesis, as well as electrochemical power sources (batteries and fuel cells).
D. R. Sadoway

3.54[J] Corrosion: The Environmental Degradation of Materials
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as22.72[J])
Prereq: 3.012
Units: 3-0-9
______
Applies thermodynamics and kinetics of electrode reactions to aqueous corrosion of metals and alloys. Application of advanced computational and modeling techniques to evaluation of materials selection and susceptibility of metal/alloy systems to environmental degradation in aqueous systems. Discusses materials degradation problems in marine environments, oil and gas production, and energy conversion and generation systems, including fossil and nuclear.
R. G. Ballinger

3.560 Industrial Ecology of Materials
______

Graduate (Fall)
(Subject meets with3.081)
Prereq: 3.20 or permission of instructor
Units: 3-0-9
Lecture: MW2.30-4 (8-205)
______
Covers quantitative techniques to address principles of substitution, dematerialization, and waste mining implementation in materials systems. Includes life-cycle and materials flow analysis of the impacts of materials extraction; processing; use; and recycling for materials, products, and services. Student teams undertake a case study regarding materials and technology selection using the latest methods of analysis and computer-based models of materials process. Students taking graduate version complete additional assignments.
E. Olivetti
No required or recommended textbooks

3.57 Materials Selection, Design, and Economics
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
______
A survey of techniques for analyzing how the choice of materials, processes, and design determine properties, performance, and cost. Topics include production and cost functions, mathematical optimization, evaluation of single and multi-attribute utility, decision analysis, materials property charts, and performance indices. Students use analytical techniques to develop a plan for starting a new materials-related business.
Staff

3.60 Symmetry, Structure, and Tensor Properties of Materials
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with3.072)
Prereq: 3.016 or 18.03
Units: 4-0-8
URL: http://www-swiss.ai.mit.edu/~astark/crystal.html
Subject Cancelled Subject Cancelled
______
Studies the underlying structures of materials and deepens understanding of the relationship between the properties of materials and their structures. Topics include lattices, point groups, and space groups in both two and three dimensions; the use of symmetry in the tensor representation of crystal properties; and the relationship between crystalline structure and properties, including transport properties, piezoelectricity, and elasticity. Students taking graduate version complete additional assignments.
R. Taylor, E. Fitzgerald

3.65 Soft Matter Characterization
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 2-1-9
______
Focuses on the design and execution of advanced experiments to characterize soft materials, such as synthetic and natural polymers, biological composites, and supramolecular nanomaterials. Each week focuses on a new characterization technique explored through interactive lectures, demonstrations, and lab practicum sessions in which students gain experience in key experimental aspects of soft matter sample preparation and characterization. Among others, topics include chemical characterization, rheology and viscometry, microscopy, and spectroscopic analyses. Limited to 15.
J. Ortony

3.69 Teaching Fellows Seminar
______

Graduate (Fall) Can be repeated for credit
Prereq: None
Units: 2-0-1
TBA.
______
Provides instruction to help prepare students for teaching at an advanced level and for industry or academic career paths. Topics include preparing a syllabus, selecting a textbook, scheduling assignments and examinations, lecture preparation, "chalk and talk" vs. electronic presentations, academic honesty and discipline, preparation of examinations, grading practices, working with teaching assistants, working with colleagues, mentoring outside the classroom, pursuing academic positions, teaching through technical talks, and successful grant writing strategies.
C. Schuh
No textbook information available

3.691 Teaching Materials Science and Engineering
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 0-1-0 [P/D/F]
TBA.
______
Provides classroom or laboratory teaching experience under the supervision of faculty member(s). Students assist faculty by preparing instructional materials, leading discussion groups, and monitoring students' progress. Limited to Course 3 undergraduates selected by Teaching Assignments Committee.
G. Beach
No required or recommended textbooks

3.692 Teaching Materials Science and Engineering
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Provides classroom or laboratory teaching experience under the supervision of faculty member(s). Students assist faculty by preparing instructional materials, leading discussion groups, and monitoring students' progress. Credit arranged on a case-by-case basis and reviewed by the department. Limited to Course 3 undergraduates selected by Teaching Assignments Committee.
G. Beach
No required or recommended textbooks

3.693-3.699 Teaching Materials Science and Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
Subject Cancelled 3.693 Cancelled
Subject Cancelled 3.695 Cancelled
Subject Cancelled 3.696 Cancelled
3.697: TBA.
Subject Cancelled 3.698 Cancelled
Subject Cancelled 3.699 Cancelled
______
Laboratory, tutorial, or classroom teaching under the supervision of a faculty member. Students selected by interview. Enrollment limited by availability of suitable teaching assignments.
D. Sadoway
3.697: No required or recommended textbooks

3.70 Materials Science and Engineering of Clean Energy
______

Graduate (Spring)
(Subject meets with3.18)
Prereq: 3.20, 3.23, or permission of instructor
Units: 3-0-9
______
Develops the materials principles, limitations and challenges in clean energy technologies, including solar, energy storage, thermoelectrics, fuel cells, and novel fuels. Draws correlations between the limitations and challenges related to key figures of merit and the basic underlying thermodynamic, structural, transport, and physical principles, as well as to the means for fabricating devices exhibiting optimum operating efficiencies and extended life at reasonable cost. Students taking graduate version complete additional assignments.
H. Tuller, K. Van Vliet

3.903[J] Seminar in Polymers and Soft Matter
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as10.960[J])
Prereq: None
Units: 2-0-0 [P/D/F]
Lecture: W3-5 (56-114)
______
A series of seminars covering a broad spectrum of topics in polymer science and engineering, featuring both on- and off-campus speakers.
A. Alexander-Katz, R. E. Cohen, D. Irvine
No required or recommended textbooks

3.91 Mechanical Behavior of Polymers
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/course/3/3.91/www/
______
Influence of processing and structure on mechanical properties of synthetic and natural polymers: Hookean and entropic elastic deformation, linear viscoelasticity, composite materials and laminates, yield and fracture. Introductory subjects in solid mechanics and polymers recommended, e.g. 3.032, 3.034.
Staff

3.930 Internship Program
______

Undergrad (Summer)
Prereq: None
Units: 0-6-0 [P/D/F]
______
Provides academic credit for first approved materials science and engineering internship. For reporting requirements, consult the faculty internship program coordinator. Limited to Course 3 internship track majors.
T. Eagar
No textbook information available

3.931 Internship Program
______

Undergrad (Summer)
Prereq: 3.930
Units: 0-6-0
______
Provides academic credit for second approved materials science and engineering internship in the year following completion of 3.930. For reporting requirements consult the faculty internship program coordinator. Limited to Course 3 internship track majors.
T. Eagar
No textbook information available

3.932 Industrial Practice
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Provides academic credit to graduate students for approved work assignments at companies/national laboratories. Restricted to DMSE SM or PhD/ScD students.
D. Sadoway
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

3.94 Morphology of Polymers
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 3.063
Units: 3-0-6
______
Structure of noncrystalline, crystalline, and liquid crystalline polymers, including polymers blends, and block copolymers. Texture development from processing operations, mechanical deformation, and applied electric and magnetic fields. Hybrid organic-inorganic nano and microcomposites. Phase transformations, including classical nucleation theory and spinodal decomposition. Use of morphological characterization methods such as wide- and small-angle x-ray scattering and scanning, transmission electron microscopy and atomic force microscopy are also covered.
Staff

3.941[J] Statistical Mechanics of Polymers
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as10.668[J])
Prereq: 10.568 or permission of instructor
Units: 3-0-9
______
Concepts of statistical mechanics and thermodynamics applied to macromolecules: polymer conformations in melts, solutions, and gels; Rotational Isomeric State theory, Markov processes and molecular simulation methods applied to polymers; incompatibility and segregation in incompressible and compressible systems; molecular theory of viscoelasticity; relation to scattering and experimental measurements.
G. C. Rutledge, A. Alexander-Katz

3.942 Polymer Physics
______

Graduate (Spring)
(Subject meets with3.063)
Prereq: 3.032 or permission of instructor
Units: 4-0-8
______
The mechanical, optical, electrical, and transport properties of polymers and other types of "soft matter" are presented with respect to the underlying physics and physical chemistry of polymers and colloids in solution, and solid states. Topics include how enthalpy and entropy determine conformation, molecular dimensions and packing of polymer chains and colloids and supramolecular materials. Examination of the structure of glassy, crystalline, and rubbery elastic states of polymers; thermodynamics of solutions, blends, crystallization; liquid crystallinity, microphase separation, and self-assembled organic-inorganic nanocomposites. Case studies of relationships between structure and function in technologically important polymeric systems. Students taking graduate version complete additional assignments.
A. Alexander-Katz

3.96[J] Biomaterials: Tissue Interactions
______

Graduate (Fall)
(Same subject as 2.79[J],HST.522[J])
Prereq: Chemistry (GIR), Biology (GIR), Physics I (GIR); or permission of instructor
Units: 3-0-9
Lecture: TR2.30-4 (3-370)
______
Principles of materials science and cell biology underlying the development and implementation of biomaterials for the fabrication of medical devices/implants, including artificial organs and matrices for tissue engineering and regenerative medicine. Employs a conceptual model, the "unit cell process for analysis of the mechanisms underlying wound healing and tissue remodeling following implantation of biomaterials/devices in various organs, including matrix synthesis, degradation, and contraction. Methodology of tissue and organ regeneration. Discusses methods for biomaterials surface characterization and analysis of protein adsorption on biomaterials. Design of implants and prostheses based on control of biomaterials-tissue interactions. Comparative analysis of intact, biodegradable, and bioreplaceable implants by reference to case studies. Criteria for restoration of physiological function for tissues and organs.
I. V. Yannas, M. Spector
Textbooks (Fall 2016)

3.961[J] Design of Medical Devices and Implants
______

Graduate (Spring)
(Same subject as2.782[J],HST.524[J])
Prereq: Chemistry (GIR), Biology (GIR), Physics I (GIR); or permission of instructor
Units: 3-0-9
______
Solution of clinical problems by use of implants and other medical devices. Systematic use of cell-matrix control volumes. The role of stress analysis in the design process. Anatomic fit: shape and size of implants. Selection of biomaterials. Instrumentation for surgical implantation procedures. Preclinical testing for safety and efficacy: risk/benefit ratio assessment. Evaluation of clinical performance: design of clinical trials. Project materials drawn from orthopedic devices, soft tissue implants, artificial organs, and dental implants.
I. V. Yannas, M. Spector

3.963[J] Biomaterials Science and Engineering
______

Graduate (Fall)
(Same subject as20.463[J])
(Subject meets with3.055[J],20.363[J])
Prereq: 3.034, 20.110, or permission of instructor
Units: 3-0-9
Lecture: MW11-12.30 (56-614)
______
Covers, at a molecular scale, the analysis and design of materials used in contact with biological systems, and biomimetic strategies aimed at creating new materials based on principles found in biology. Topics include molecular interaction between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of materials science to problems in tissue engineering, drug delivery, vaccines, and cell-guiding surfaces. Students taking graduate version complete additional assignments.
D. Irvine, K. Ribbeck
No textbook information available

3.97[J] Cell-Matrix Mechanics
______

Graduate (Fall)
(Same subject as2.785[J],HST.523[J])
Prereq: 2.001, or 2.01 and 2.02A; Chemistry (GIR), Biology (GIR); or permission of instructor
Units: 3-0-9
Lecture: TR11-12.30 (1-371)
______
Mechanical forces play a decisive role during development of tissues and organs, during remodeling following injury as well as in normal function. A stress field influences cell function primarily through deformation of the extracellular matrix to which cells are attached. Deformed cells express different biosynthetic activity relative to undeformed cells. The unit cell process paradigm combined with topics in connective tissue mechanics form the basis for discussions of several topics from cell biology, physiology, and medicine.
I. V. Yannas, M. Spector
No required or recommended textbooks

3.971[J] Molecular, Cellular, and Tissue Biomechanics
______

Graduate (Fall)
(Same subject as2.798[J],6.524[J],10.537[J],20.410[J])
Prereq: Biology (GIR); 2.002, 2.006, 6.013, 10.301, or 10.302
Units: 3-0-9
Lecture: TR10.30-12 (2-143)
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, K. J. Van Vliet
No textbook information available

3.98 Polymer Synthetic Chemistry
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: One basic polymer chemistry subject
Units: 3-0-6
______
An examination of the fundamental reaction mechanisms and chemistry of polymerization reactions with an emphasis on the synthesis of new advanced polymers and their properties.
M. F. Rubner

Archaeology and Archaeological Science

3.981 Communities of the Living and the Dead: the Archaeology of Ancient Egypt
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-0-9
______
Examines the development of complex societies in Egypt over a 3000-year period. Uses archaeological and historical sources to determine how and why prehistoric communities coalesced into a long-lived and powerful state. Studies the remains of ancient settlements, tombs, and temples, exploring their relationships to one another and to the geopolitical landscape of Egypt and the Mediterranean world. Considers the development of advanced technologies, rise of social hierarchy, expansion of empire, role of writing, and growth of a complex economy.
K. Grossman

3.982 The Ancient Andean World
______

Undergrad (Fall) HASS Social Sciences
Prereq: None
Units: 3-0-6
Lecture: T EVE (7-10 PM) (4-153)
______
Examines development of Andean civilization which culminated in the extraordinary empire established by the Inka. Archaeological, ethnographic, and ethnohistorical approaches. Particular attention to the unusual topography of the Andean area, its influence upon local ecology, and the characteristic social, political, and technological responses of Andean people to life in a topographically "vertical" world. Characteristic cultural styles of prehistoric Andean life.
H. N. Lechtman
Textbooks (Fall 2016)

3.983 Ancient Mesoamerican Civilization
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Examines development of selected ancient Mesoamerican civilizations using archaeological and ethnohistorical evidence. Focuses on Olmec, Maya, Teotihuacan and Aztec, considering key technological, environmental, social organizational and ideological variables. Includes major group research project. Limited to 10.
D. Hosler

3.984 Materials in Ancient Societies: Ceramics
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-6-3
1st mtg Sept 6 at 9 am. Room 16-536. TBA.
______
Seminars and labs provide in-depth study of the technologies ancient societies used to produce objects from ceramic materials, including clays and mortars. Seminars cover basic ceramic materials science and engineering and relate materials selection and processing to environment, exchange, political power, and cultural values.
H. N. Lechtman, J. Meanwell
Textbooks (Fall 2016)

3.985[J] Archaeological Science
______

Undergrad (Spring) HASS Social Sciences
(Same subject as5.24[J],12.011[J])
Prereq: Chemistry (GIR) or Physics I (GIR)
Units: 3-1-5
______
Pressing issues in archaeology as an anthropological science. Stresses the natural science and engineering methods archaeologists use to address these issues. Reconstructing time, space, and human ecologies provides one focus; materials technologies that transform natural materials to material culture provide another. Topics include 14C dating, ice core and palynological analysis, GIS and other remote sensing techniques for site location, soil micromorphology and site formation, sourcing of metal artifacts, and microstructural and mechanical analyses of cementitious materials used in ancient monumental buildings.
H. N. Lechtman

3.986 The Human Past: Introduction to Archaeology
______

Undergrad (Fall) HASS Social Sciences Communication Intensive HASS
Prereq: None
Units: 3-0-9
Lecture: TR3 (4-231) Recitation: T4 (4-145) or R4 (4-145)
______
From an archaeological perspective, examines ancient human activities and the forces that shaped them. Draws on case studies from the Old and/or New World. Exposes students to various classes of archaeological data, such as stone, bone, and ceramics, that help reconstruct the past.
K. Grossman
No required or recommended textbooks

3.987 Human Evolution: Data from Palaeontology, Archaeology, and Materials Science
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-6-3
______
Examines human physical and cultural evolution over the past five million years via lectures and labs that incorporate data from human palaeontology, archaeology, and materials science. Topics include the evolution of hominin morphology and adaptations; the nature and structure of bone and its importance in human evolution; and the fossil and archaeological evidence for human behavioral and cultural evolution, from earliest times through the Pleistocene. Laboratory sessions include study of stone technology, artifacts, and fossil specimens.
K. Grossman

3.989 Materials in Ancient Societies: Ceramics Laboratory
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-6-3
______
Laboratory analysis of archaeological artifacts of ceramics. Follows on 3.984.
D. Hosler, J. Meanwell

3.990 Seminar in Archaeological Method and Theory
______

Undergrad (Fall, Spring)
Prereq: 3.985, 3.986, 21A.00
Units: 3-0-6
TBA.
______
Designed for undergraduate seniors majoring in Archaeology and Materials. Critical analysis of major intellectual and methodological developments in American archaeology, including evolutionary theory, the "New Archaeology," Marxism, formal and ideological approaches. Explores the use of science and engineering methods to reconstruct cultural patterns from archaeological data. Seminar format, with formal presentations by all students. Non-majors fulfilling all prerequisites may enroll by permission of instructors. Instruction and practice in oral and written communication provided.
D. Hosler, H. Lechtman, H. Merrick
No textbook information available

3.993 Archaeology of the Middle East
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-0-6
______
Focus on the rise of settled communities, cities, and empires and their technological achievements in various areas of the Middle East including Anatolia, the Levant, and Mesopotamia. Using archaeological and written sources, examines why such complex societies arose in this area. Considers the technological basis of these societies; the role of temples and religious hierarchies, of crafts and trade in luxury goods, of writing and bureaucracies, and of class stratification in the rise of early civilizations.
Staff

3.997 Graduate Fieldwork in Materials Science and Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of field research in materials science and engineering leading to the writing of an SM, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member.
H. Lechtman
No textbook information available

3.998 Doctoral Thesis Update Meeting
(New)
______

Graduate (Fall, Spring)
Prereq: None
Units: 0-1-0 [P/D/F]
TBA.
______
Thesis research update presentation to the thesis committee. Held the first or second academic term after successfully passing the Thesis Area Examination.
Staff
No required or recommended textbooks

3.EPE UPOP Engineering Practice Experience
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.EPE,2.EPE,3.EPE,6.EPE,10.EPE,16.EPE,22.EPE)
Prereq: 2.EPW or permission of instructor
Units: 0-0-1 [P/D/F]
TBA.
______
Provides sophomores with guided practice in finding opportunities and excelling in the world of practice. Building on the skills and relationships acquired in the Engineering Practice Workshop, students receive coaching to articulate goals, invoke the UPOP network of mentors and employers, identify and pursue opportunities and negotiate terms of their summer assignment. Students complete a 10-12 week internship, which includes filing three progress reports, conducting one informational interview, and possibly hosting a site visit by MIT staff. Returning to campus as juniors, UPOP students take part in reflective exercises that aid assimilation of learning objectives and reinforce the cognitive link between all aspects of the UPOP experience and disciplinary fields of study. Sequence begins in the spring of sophomore year and ends in the fall of junior year.
Staff
No textbook information available

3.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No textbook information available

3.S01 Special Subject in Materials Science and Engineering
______

Undergrad (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: TR11-12.30 (2-131)
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff
No textbook information available

3.S02 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S03 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S04 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S05 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer)
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S06 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer)
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S07 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S08 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer)
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S09 Special Subject in Materials Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer)
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Lecture, seminar, or laboratory consisting of material not offered in regularly scheduled subjects. Can be repeated for credit only for completely different subject matter.
Staff

3.S70-3.S75 Special Subject in Materials Science and Engineering
______

Graduate (Fall, IAP, Spring, Summer)
Prereq: Permission of instructor
Units arranged
3.S70: Lecture: TR11-12.30 (2-131)
3.S71: TBA.
3.S72: TBA.
3.S73: TBA.
3.S74: TBA.
3.S75: TBA.
______
Covers advanced topics in Materials Science and Engineering that are not included in the permanent curriculum.
Staff
3.S70: No textbook information available
3.S71: No textbook information available
3.S72: No textbook information available
3.S73: No textbook information available
3.S74: No textbook information available
3.S75: No textbook information available

3.S76-3.S79 Special Subject in Materials Science and Engineering
______

Graduate (Fall, IAP, Spring, Summer)
Prereq: Permission of instructor
Units arranged [P/D/F]
3.S76: TBA.
3.S77: TBA.
3.S78: TBA.
3.S79: TBA.
______
Covers advanced topics in Materials Science and Engineering that are not included in the permanent curriculum.
Staff
3.S76: No textbook information available
3.S77: No textbook information available
3.S78: No textbook information available
3.S79: No textbook information available

3.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of an SM, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member.
D. Sadoway
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

3.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Program of research leading to the writing of an SB thesis; to be arranged by the student and an appropriate MIT faculty member. Instruction and practice in oral and written communication.
Information: DMSE Academic Office
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

3.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

3.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Extended participation in work of a research group. Independent study of literature, direct involvement in group's research (commensurate with student skills), and project work under an individual faculty member. See UROP coordinator for registration procedures.
Information: DMSE Academic Office
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|3.00-3.499|3.50-3.999 plus UROP, UPOP, and Thesis|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 4: Architecture
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Course 4: Architecture
Fall 2016


Architecture Design

4.021 Introduction to Architecture Design
______

Undergrad (Fall) HASS Arts
Prereq: None
Units: 3-3-6
Credit cannot also be received for4.02A
URL: http://architecture.mit.edu/subject/fall-2016-4021
Design: MW2-5 (3-133) +final
______
Provides an introduction to the architecture design process. Develops skills that enable design creativity, thinking, representation, and development. Beginning with abstract exercises, introduces techniques for designing and developing 2-dimensional and 3-dimensional form and space in architecture.
L. Bello Bomez, A. Garcia-Abril
No textbook information available

4.022 Architecture Design Foundations
______

Undergrad (Spring)
Prereq: None
Units: 3-3-6
______
Provides the foundations for architectural design. Focuses on design methodologies, formal and spatial analysis and the translation of creative conceptual strategies into architectural design propositions. Instruction in design skills, including digital and analogue representational techniques. Preference to Course 4 majors and minors.
Architecture Design Staff

4.023 Architecture Design Studio I
______

Undergrad (Fall)
Prereq: 4.021, 4.022
Units: 0-12-12
URL: http://architecture.mit.edu/subject/fall-2016-4023
Design: TRF1-5 (7-434) +final
______
Provides instruction in architectural design and project development within design constraints including architectural program and site. Students engage the design process through various 2-dimensional and 3-dimensional media. Working directly with representational and model making techniques, students gain experience in the conceptual, formal, spatial and material aspects of architecture. Instruction and practice in oral and written communication provided. Preference to Course 4 majors and minors.
C. Abbanat, C. Parreno
No required or recommended textbooks

4.024 Architecture Design Studio II
______

Undergrad (Spring)
Prereq: 4.023, 4.401, 4.500
Units: 0-12-12
______
Provides instruction in architectural design and project development with an emphasis on social, cultural, or civic programs. Builds on foundational design skills with more complex constraints and contexts. Integrates aspects of architectural theory, building technology, and computation into the design process. Preference to Course 4 majors.
Architecture Design Staff

4.025 Architecture Design Studio III
______

Undergrad (Fall)
Prereq: 4.024, 4.440
Units: 0-12-12
URL: http://architecture.mit.edu/subject/fall-2016-4025
Design: TRF1-5 (7-434) +final
______
Provides instruction in more advanced architectural design projects. Students develop integrated design skills as they negotiate the complex issues of program, site, and form in a specific cultural context. Focuses on how architectural concepts and ideas translate into built environments that transform the public sphere. Studio designed to prepare students for graduate studies in the field. Preference to Course 4 majors.
J. Klein
No textbook information available

4.02A Introduction to Architecture Design Intensive
______

Undergrad (IAP) HASS Arts
Prereq: None
Units: 2-5-2
Credit cannot also be received for4.021
______
Provides an introduction to the architecture design process. Develops skills that enable design creativity, thinking, representation, and development. Beginning with abstract exercises, introduces techniques for designing and developing 2-dimensional and 3-dimensional form and space in architecture.
Architecture Design Staff

4.031 Design Studio: Objects and Interaction
(New)
______

Undergrad (Fall)
Prereq: None
Units: 2-4-6
URL: http://architecture.mit.edu/subject/fall-2016-4031
Lecture: TR2-5 (7-434) +final
______
Overview of design as the giving of form, order, and interactivity to the objects that define our daily life. Follows the path from project to interactive product. Covers the overall design process, preparing students for work in a hands-on studio learning environment. Emphasizes design development and constraints. Topics include the analysis of objects; interaction design and user experience; design methodologies, current dialogues in design; economies of scale vs. means; and the role of technology in design. Provides a foundation in prototyping skills such as carpentry, casting, digital fabrication, electronics, and coding.
M. Coelho
No textbook information available

4.032 Design Studio: Information and Visualization
(New)
______

Undergrad (Spring)
Prereq: None
Units: 2-4-6
______
Provides an introduction to working with information, data and visualization in a hands-on studio learning environment. Studies the history and theory of information, followed by a series of projects in which students apply the ideas directly. Progresses though basic data analysis, visual design and presentation, and more sophisticated interaction techniques. Topics include storytelling and narrative, choosing representations, understanding audiences, and the role of designers working with data.
Staff

4.091 Independent Study in Design
(New)
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No required or recommended textbooks

4.092 Independent Study in Design
(New)
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

4.093 Independent Study in Design
(New)
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.094 Independent Study in Design
(New)
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual or group basis. Registration subject to prior arrangement for subject matter and supervision by staff.
Staff
No required or recommended textbooks

4.100 Architecture Workshop: Form and Material
______

Undergrad (IAP)
Prereq: None
Units: 0-3-0 [P/D/F]
______
Intensive design and fabrication workshop in which students create models and half-size prototypes that explore the characteristics of concrete and wood. Examines the behavior of these materials and their inherent structural qualities. Studies how architectural detail can impact the perception and creation of larger built structures and environments. Lab fee. Limited to 15; preference to freshmen.
Staff

4.101 Design Studio: Introduction to Design Techniques and Technologies
______

Undergrad (Spring)
Prereq: None
Units: 2-4-6
______
Introduces core principles, techniques and technologies for design across a wide range of media in a studio environment. Explores ideas related to form, materials, tools, systems, and structures through project-based exercises. Develops familiarity with design process, critical observation, and tools for the translation of design concepts into digital and physical constructs. Utilizing traditional and contemporary tools, faculty across various design disciplines expose students to a unique cross-section of inquiry.
C. Mueller, S. Tibbits

4.105 Geometric Disciplines and Architecture Skills I
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-2-5
URL: http://architecture.mit.edu/subject/fall-2016-4105
Design: M2-5 (3-442) +final
______
Intensive introduction to architectural design tools and process, taught through a series of short exercises. Together with 4.107, covers a broad range of topics relating to the discourse of geometry as the basis of architectural design process. Focuses on projective drawings, explicit 3D modeling, and the reciprocity between representation and materialization. Lectures, workshops, and pin-ups address the architectural arguments intrinsic to geometry and its representation. Restricted to level one MArch students.
J. Lamere, B. Clifford
No required or recommended textbooks

4.107 Geometric Disciplines and Architecture Skills II
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 4.105
Units: 2-2-5
______
Intensive investigation of advanced architectural design tools and process, taught through a series of progressive exercises. Together with 4.105, covers a broad range of topics relating to the discourse of geometry as the basis of architectural design process. Focuses on contemporary digital modeling tools, including parametric and solver-based modeling and their relationship to digital fabrication. Lectures, workshops, and pin-ups address the architectural implications of simulations and innovative means of making. Restricted to first-year MArch students.
Architecture Design Staff

4.109 Materials and Fabrication for Architecture
______

Graduate (IAP)
Prereq: Permission of instructor
Units: 0-3-6
______
Provides the material system knowledge and fabrication process skills to successfully engage with all areas of the shop, from precision handwork to multi-axis computer numerically controlled (CNC) machining. Progresses through a series of basic exercises that introduce the material and workflow, concluding with more complex problems that explore opportunities and issues specific to architecture. Lab fee. Limited to 12; preference to first-year MArch students.
J. Lavallee

4.110 Design Across Scales and Disciplines
______

Undergrad (Spring) HASS Arts
(Subject meets withMAS.650)
Prereq: None
Units: 2-2-8
______
Inspired by Charles and Ray Eames' canonical Powers of Ten, explores the relationship between science and engineering through the lens of design. Examines how transformations in science and technology have influenced design thinking and vice versa. Provides interdisciplinary skills and methods to represent, model, design and fabricate objects, machines, and systems using new computational and fabrication tools. Aims to develop methodologies for design research of interdisciplinary problems. Additional work required of students taking the graduate version of the subject. Enrollment limited; preference to Course 4 minors.
N. Oxman, J. M. Yoon

4.119 Preparation for Undergraduate Architecture Design Thesis
______

Undergrad (Fall)
Prereq: 4.024
Units: 2-0-10
URL: http://architecture.mit.edu/subject/fall-2016-4119
Lecture: F10
______
Selection of thesis topic, defining method of approach, and preparation of thesis proposal for BSA degree in architecture. Weekly class meeting as well as individual conference with faculty.
J. Lamere
No textbook information available

4.120 Furniture Making Workshop
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 2-2-5
URL: http://architecture.mit.edu/subject/fall-2016-4120
Subject Cancelled Subject Cancelled
______
Provides instruction in designing and building a functional piece of furniture from an original design. Develops woodworking techniques from use of traditional hand tools to digital fabrication. Gives students the opportunity to practice design without using a building program or code. Surveys the history of furniture making and includes site visits to local collections and artists/craftsmen. Limited to 12; preference to Course 4 students.
C. Dewart

4.130 Architectural Design Theory and Methodologies
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4130
Lecture: T9-11 (5-216)
______
Studies design as an interrogative technique to examine material sciences, media arts and technology, cultural studies, computation and emerging fabrication protocols. Provides in-depth, theoretical grounding to the notion of 'design' in architecture, and to the consideration of contemporary design methodologies, while encouraging speculation on emerging design thinking. Topical focus varies with instructor. May be repeated for credit with permission of department.
M. Goulthorpe
No textbook information available

4.140[J] How to Make (Almost) Anything
______

Graduate (Fall)
(Same subject asMAS.863[J])
Prereq: Permission of instructor
Units: 3-9-6
URL: http://architecture.mit.edu/subject/fall-2016-4140
Lecture: W1-4 (E14-633) +final
______
Provides a practical hands-on introduction to digital fabrication, including CAD/CAM/CAE, NC machining, 3-D printing and scanning, molding and casting, composites, laser and waterjet cutting, PCB design and fabrication; sensors and actuators; mixed-signal instrumentation, embedded processing, and wired and wireless communications. Develops an understanding of these capabilities through projects using them individually and jointly to create functional systems.
N. Gershenfeld, J. DiFrancesco, S. Tibbits
No textbook information available

4.151 Architecture Design Core Studio I
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 0-12-9
URL: http://architecture.mit.edu/subject/fall-2016-4151
Design: TRF1-5 (STUDIO) or TRF1-5 (STUDIO) or TRF1-5 (STUDIO)
______
Establishes foundational processes, techniques and attitudes towards architectural design. Includes projects of increasing scope and complexity engaging issues of structure, circulation, program, organization, building systems, materiality and tectonics. Develops methods of representation that incorporate both analogue and digital drawings and models. First in a sequence of design subjects, which must be taken in order. Limited to first-year MArch students.
B. Clifford, W. O'Brien
No required or recommended textbooks

4.152 Architecture Design Core Studio II
______

Graduate (Spring)
Prereq: 4.151
Units: 0-12-9
______
Builds on Core I skills and expands the constraints of the architectural problem to include issues of urban site logistics, cultural and programmatic material (inhabitation and human factors), and long span structures. Two related projects introduce a range of disciplinary issues, such as working with precedents, site, sectional and spatial proposition of the building, and the performance of the outer envelope. Emphasizes the clarity of intentions and the development of appropriate architectural and representational solutions. Limited to first-year MArch students.
Architecture Design Staff

4.153 Architecture Design Core Studio III
______

Graduate (Fall)
Prereq: 4.152
Units: 0-12-9
URL: http://architecture.mit.edu/subject/fall-2016-4153
Design: TRF1-5 (STUDIO) or TRF1-5 (STUDIO) or TRF1-5 (STUDIO)
______
Interdisciplinary approach to design through studio design problems that engage the domains of building technology, computation, and the cultural/historical geographies of energy. Uses different modalities of thought to examine architectural agendas for 'sustainability'; students position their work with respect to a broader understanding of the environment and its relationship to society and technology. Students develop a project with a comprehensive approach to programmatic organization, energy load considerations, building material assemblies, exterior envelope and structure systems. Limited to second-year MArch students.
S. Kennedy, A. Anmahian, C. Banon
No required or recommended textbooks

4.154 Architecture Design Option Studio
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 4.153
Units: 0-10-11
URL: http://architecture.mit.edu/subjects
Design: TRF1-5 (STUDIO) or TRF1-5 (STUDIO)
______
Offers a broad range of advanced-level investigations in architectural design in various contexts, including international sites. Integrates theoretical and technological discourses into specific topics. Studio problems may include urbanism and city scale strategies, habitation and urban housing systems, architecture in landscapes, material investigations and new production technologies, programmatic and spatial complex building typologies, and research centered studies. Mandatory lottery process.
Architecture Design Staff
No required or recommended textbooks

4.162 Introductory Urban Design Studio
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 0-10-11
URL: http://architecture.mit.edu/subject/fall-2016-4162
Design: TR EVE (1-6 PM) (STUDIO)
______
Project-based introduction to urban observation, research, analysis, and design. Focuses on urban elements, urban and architectural interventions, and landscape in existing cities. Emphasizes city form, sustainability, and social conditions. Projects require both conventional and digital techniques. Preference to Urbanism SMArchS students.
M. Mazereeuw, A. Berger, F. Masoud
No required or recommended textbooks

4.163[J] Urban Design Studio
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as11.332[J])
Prereq: 4.162 or permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4163
Design: TR EVE (1-6 PM) (STUDIO)
______
The design of urban environments. Strategies for change in large areas of cities, to be developed over time, involving different actors. Fitting forms into natural, man-made, historical, and cultural contexts; enabling desirable activity patterns; conceptualizing built form; providing infrastructure and service systems; guiding the sensory character of development. Involves architecture and planning students in joint work; requires individual designs or design and planning guidelines.
M. Mazereeuw, A. Berger, F. Masoud
No textbook information available

4.173[J] Beijing Urban Design Studio
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as11.307[J])
Prereq: Permission of instructor
Units: 0-18-0
TBA.
______
Design studio that includes architects and city planners working in teams on a contemporary development project of importance in China. Students analyze conditions, explore alternatives, and synthesize architecture, city design, and implementation plans. Lectures and brief study tours expose students to history and contemporary issues of urbanism in China. Offered every other summer in residence at Tsinghua University, Beijing, involving students and faculty from both schools. Limited to 10.
D. Frenchman, C. Zegras
No textbook information available

4.180 Architectural Design Workshop
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: 4.023 or permission of instructor
Units arranged
______

4.181 Architectural Design Workshop
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4181
1st mtg Sept 7 at 2-5 pm. N51-1st floor (poplab). TBA.
______
No textbook information available

4.182 Architectural Design Workshop
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4182
TBA.
______
No textbook information available

4.183-4.185 Architectural Design Workshop
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
4.183: URL: http://architecture.mit.edu/subject/fall-2016-4183
4.184: URL: http://architecture.mit.edu/subject/fall-2016-4184
4.183: 1st mtg Sept 7 at 5 pm. Room 10-471. TBA.
4.184: 1st mtg Sept 7 at 4 pm. Room 5-232. Design: TBA
______
Addresses design inquiry in a studio format. In-depth consideration of selected issues of the built world. The problem may be prototypical or a particular aspect of a whole project, but is always interdisciplinary in nature.
Architecture Design Staff
4.183: No textbook information available
4.184: No textbook information available

4.189 Preparation for MArch Thesis
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-1-5
TBA.
______
Preparatory research development leading to a well-conceived proposition for the MArch design thesis. Students formulate a cohesive thesis argument and critical project using supportive research and case studies through a variety of representational media, critical traditions, and architectural/artistic conventions. Group study in seminar and studio format, with periodic reviews supplemented by conference with faculty and a designated committee member for each individual thesis. Restricted to MArch students.
Architecture Design Staff
No textbook information available

4.190 Practical Experience in Architecture
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 0-0-3 [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4190
See advisor. TBA.
______
Practical experience through summer internships secured by the student in the field of architecture, urbanism, digital design, art, or building technology. Registration limited to two summers. Restricted to Course 4 students
Staff
No required or recommended textbooks

4.191 Independent Study in Architecture Design
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.192 Independent Study in Architecture Design
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

4.193 Independent Study in Architecture Design
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.194 Independent Study in Architecture Design
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual or group basis. Registration subject to prior arrangement for subject matter and supervision by staff.
Architecture Design Staff
No required or recommended textbooks

4.S00 Special Subject: Design
(New)
______

Undergrad (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: permission of instructor
Units arranged
______
Seminar or lecture on a topic in design that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Staff

4.S02 Special Subject: Design
(New)
______

Graduate (Fall) Can be repeated for credit
Prereq: None
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4s02
Lecture: TBA
______
Seminar or lecture on a topic in design that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Staff
No textbook information available

4.S10 Special Subject: Architecture Design
______

Undergrad (Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

4.S11 Special Subject: Architecture Design
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
______

4.S12 Special Subject: Architecture Design
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.S13 Special Subject: Architecture Design
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.S14 Special Subject: Architecture Design
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Seminar or lecture on a topic in architecture design that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Architecture Design Staff


left arrow|Architecture Design|Architecture Studies|Art, Culture and Technology|Building Technology|Computation|History, Theory and Criticism of Architecture and Art|Thesis and UROP|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 4: Architecture
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Home | Subject Search | Help | Symbols Help | Pre-Reg Help | Final Exam Schedule
 

Course 4: Architecture
Fall 2016


Architecture Studies

4.210 Precedents in Critical Practice
______

Graduate (Fall)
Prereq: None
Units: 3-0-6
URL: http://architecture.mit.edu/subject/fall-2016-4210
Lecture: W2-5 (9-451) +final
______
Through formal analysis and discussion of historical and theoretical texts, seminar produces a map of contemporary architectural practice. Examines six pairs of themes in terms of their recent history: city and global economy, urban plan and map of operations, program and performance, drawing and scripting, image and surface, and utopia and projection. Restricted to year-one MArch students.
A. Miljacki
No required or recommended textbooks

4.211[J] The Once and Future City
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Humanities Communication Intensive HASS
(Same subject as11.016[J])
Prereq: None
Units: 3-0-9
______
Examines the evolving structure of cities, the dynamic processes that shape them, and the significance of a city's history for its future development. Develops the ability to read urban form as an interplay of natural processes and human purposes over time. Field assignments in Boston provide the opportunity to use, develop, and refine these concepts. Enrollment limited.
A. Spirn

4.213[J] Ecological Urbanism Seminar
______

Graduate (Fall)
(Same subject as11.308[J])
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4213
Lecture: M2-5 (10-401)
______
Examines the urban environment as a natural phenomenon, human habitat, medium of expression, and forum for action. Subject has two related, major themes: how ideas of nature influence the way cities are perceived, designed, built, and managed; and how natural processes and urban form interact and the consequences of these for human health safety and welfare. Enrollment limited.
A. Spirn
Textbooks (Fall 2016)

4.214[J] Water, Landscape and Urban Design
______

Not offered academic year 2017-2018Graduate (Spring) Can be repeated for credit
(Same subject as11.314[J])
Prereq: Permission of instructor
Units: 3-3-6
______
Workshop surveys how water affects the design of buildings, landscapes and cities in aesthetic, functional and symbolic ways. Combines the systematic study of water issues with urban design projects in South Asia and the US. Covers topics such as rainwater harvesting, water use efficiency, wastewater reuse, stormwater management, floodplain design, constructed wetlands, and waterfront development. Students work together to integrate these design concepts at the site, urban, and international scales. Limited to 15.
J. Wescoat

4.215[J] Sensing Place: Photography as Inquiry
______

Graduate (Fall)
(Same subject as11.309[J])
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4215
Lecture: W EVE (2-6 PM) (10-485)
______
Explores photography as a disciplined way of seeing, of investigating urban landscapes and expressing ideas. Readings, observations, and photographs form the basis of discussions on light, detail, place, poetics, narrative, and how photography can inform design and planning. Enrollment limited.
A. Spirn
Textbooks (Fall 2016)

4.216[J] Landscape and Urban Heritage Conservation
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
(Same subject as11.316[J])
Prereq: Permission of instructor
Units: 3-3-6
______
Focuses on cultural landscape history, theory, and heritage issues and projects in the Indo-Islamic realm. Landscape and urban heritage inquiry go beyond monuments to encompass sites, cites, and regions. Combines the study of conservation theory and practice with an exploration of active urban landscape planning and design projects. Limited to 15.
J. Wescoat

4.217[J] Disaster Resilient Design
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as11.315[J])
Prereq: None
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Seminar examines the linkages between natural hazards and environmental design. Engages theoretical debates about landscapes of risk, vulnerability, and resilience. Participants generate proposals for disaster resilience through combinations of retrofit, reconstruction, resettlement, commemorative, and anticipatory design. Methods include rapid bibliographic search, risk analysis, landscape synthesis, and comparative international methods. Projects vary and may focus on current crises or involve collaboration with the Aga Khan Development Network and other humanitarian organizations. Limited to 15.
J. Wescoat

4.221 Architecture Studies Colloquium
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-1-3
URL: http://architecture.mit.edu/subject/fall-2016-4221
Lecture: R9-11 (3-133)
______
Series of open lectures, presented as an introduction to the diverse academic and creative community of MIT and the region, at which discipline groups of the SMArchS program converge and exchange ideas. Organized thematically, guest speakers from cultural and scientific fields present viewpoints in areas of emerging interest within design, building technology, architectural computation, history, and art. Encourages discourse with speakers and among students from different disciplines. Students initiate online debates among their peers and respond to an evolving series of discussions resulting in publication.
R. Ghosn, T. Hyde, S. Kennedy
No required or recommended textbooks

4.222 Professional Practice
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-3
URL: http://architecture.mit.edu/subject/fall-2016-4222
Lecture: F9-12 (1-135)
______
Gives a critical orientation towards a career in architectural practice. Uses historical and current examples to illustrate the legal, ethical and management concepts underlying the practice of architecture. Emphasis on facilitating design excellence and strengthening connections between the profession and academia.
A. Anmahian
No required or recommended textbooks

4.225 Urban Design Theory
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
URL: http://architecture.mit.edu/subject/fall-2016-4225
Lecture: MW11-12.30 (9-450A) +final
______
Introduces theories, concepts and precedents in urban design. Emphasizes traditional, modern and contemporary values and approaches to urban design. Research projects required. Preference to Urbanism SMArchS students.
M. Dennis
No textbook information available

4.227 Landscapes of Energy
(New)
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4227
Lecture: T9-12 (10-401)
______
Spatializes large technological systems of energy, analyzes existing and speculative energy visions, and imagines energy futures in relation to concerns of ecology, politics, and aesthetics. Identifies different scales of thinking about the territory of energy from that of environmental systems, to cities, regions, and global landscapes. Readings and students' research projects draw on critical geography, history of technology, environmental history to synthesize energy attributes within the design disciplines.
R. Ghosn
No required or recommended textbooks

4.230[J] SIGUS Workshop
______

Graduate (Fall, IAP) Can be repeated for credit
(Same subject as11.468[J])
(Subject meets with4.231)
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4230
Lecture: W EVE (5-6.30 PM) (2-103)
______
No required or recommended textbooks

4.231 SIGUS Workshop
______

Undergrad (Fall, IAP) Can be repeated for credit
(Subject meets with4.230[J],11.468[J])
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4230
Lecture: W EVE (5-6.30 PM) (2-103)
______
Interdisciplinary projects and interactive practices in urban settlement issues as investigated by MIT's SIGUS (Special Interest Group in Urban Settlements), with a focus on developing countries throughout the world. Participation by guest practitioners. Additional work required of students taking the graduate version.
R. Goethert
No required or recommended textbooks

4.232[J] The New Global Planning Practitioner
______

Graduate (Spring)
(Same subject as11.444[J])
(Subject meets with4.233)
Prereq: Permission of instructor
Units: 3-0-6
______
Considers a new interdisciplinary paradigm of practice that regards dialogue among practitioners and users essential for efficacious and creative design and planning process. Focuses on non-traditional client groups: communities, the poor, and the generally excluded middle-income. Explores key issues confronting development practitioners, with stress on practical exercises drawn from current national and international case studies; e.g., an investigative comparison of cities or tools in coping with impending rapid and massive growth and expansion. Engages those with a design and community service orientation. Additional work required of students taking the graduate version.
R. Goethert

4.233 The New Global Planning Practitioner
______

Undergrad (Spring)
(Subject meets with4.232[J],11.444[J])
Prereq: Permission of instructor
Units: 3-0-6
______
Considers a new interdisciplinary paradigm of practice that regards dialogue among practitioners and users essential for efficacious and creative design and planning process. Focuses on non-traditional client groups: communities, the poor, and the generally excluded middle-income. Explores key issues confronting development practitioners, with stress on practical exercises drawn from current national and international case studies; e.g., an investigative comparison of cities or tools in coping with impending rapid and massive growth and expansion. Engages those with a design and community service orientation. Additional work required of students taking the graduate version.
R. Goethert

4.236[J] Structuring Low-Income Housing Projects in Developing Countries
______

Graduate (Fall)
(Same subject as11.463[J])
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4236
Lecture: R9-12 (1-375) +final
______
Examines dynamic relationship among key actors: beneficiaries, government, and funder. Emphasis on cost recovery, affordability, replicability, user selection, and project administration. Extensive case examples provide basis for comparisons.
R. Goethert
No required or recommended textbooks

4.240[J] Urban Design Skills: Observing, Interpreting, and Representing the City
______

Graduate (Fall)
(Same subject as11.328[J])
Prereq: None
Units: 4-2-9
URL: http://architecture.mit.edu/subject/fall-2016-4240
Lecture: F9-1 (10-485) Recitation: W EVE (6-9 PM) (10-485)
______
Introduces methods of recording, evaluating, and representing the urban environment. Through visual observation, field analysis, measurements, interviews, and other means, students draw on their senses and develop their ability to deduce, conclude, question, and test conclusions about how the environment is used and valued. Using representational tools such as drawing, photographing, computer modeling and desktop publishing, students communicate what they observe along with their impressions and design ideas. Intended as a foundation for future studio work in urban design. Includes design-based projects.
E. Ben-Joseph
No required or recommended textbooks

4.241[J] The Making of Cities
______

Graduate (Spring)
(Same subject as11.330[J])
(Subject meets with4.251)
Prereq: 4.252 or 11.001
Units arranged
______
Examines the complex development of cities through history by tracing a diachronic accumulation of forms and spaces in specific cities, and showing how significant ideas were made manifest across distinct geographies and cultures. Emphasizes how economic, spiritual, political, geographic and technological forces have simultaneously shaped and, in turn, been influenced by the city. Additional work required of students taking graduate version.
L. Jacobi, R. Segal

4.244[J] Urban Design Seminar: Perspectives on Contemporary Practice
______

Graduate (Spring)
(Same subject as11.333[J])
Prereq: None
Units: 2-0-7
______
Examines innovations in urban design practice occurring through the work of leading practitioners in the fields of architecture, landscape architecture, and urban planning. Features lectures by major national and global practitioners in urban design. Projects and topics vary based on term and speakers but may cover architectural urbanism, landscape and ecology, arts and culture, urban design regulation and planning agencies, and citywide and regional design. Focuses on analysis and synthesis of themes discussed in presentations and discussions.
Staff

4.247[J] Urban Design Ideals and Action
______

Graduate (Spring)
(Same subject as11.337[J])
Prereq: 11.301 or permission of instructor
Units: 2-0-7
______
Examines the relationship between urban design ideals, urban design action, and the built environment through readings, discussions, presentations, and papers. Analyzes the diverse design ideals that influence cities and settlements, and investigates how urban designers use them to shape urban form. Provides a critical understanding of the diverse formal methods used to intervene creatively in both developed and developing contexts, especially pluralistic and informal built environments.
B. Ryan

4.250[J] Introduction to Urban Design and Development
______

Undergrad (Fall) HASS Humanities
(Same subject as11.001[J])
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4250
Lecture: MW11-12.30 (2-105) +final
______
Examines the evolving structure of cities and the way that cities, suburbs, and metropolitan areas can be designed and developed. Surveys the ideas of a wide range of people who have addressed urban problems. Stresses the connection between values and design. Demonstrates how physical, social, political and economic forces interact to shape and reshape cities over time.
L. Vale
No required or recommended textbooks

4.251 The Making of Cities
______

Undergrad (Spring)
(Subject meets with4.241[J],11.330[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Examines the complex development of cities through history by tracing a diachronic accumulation of forms and spaces in specific cities, and showing how significant ideas were made manifest across distinct geographies and cultures. Emphasizes how economic, spiritual, political, geographic and technological forces have simultaneously shaped and, in turn, been influenced by the city. Additional work required of students taking graduate version.
L. Jacobi, R. Segal

4.252[J] Introduction to Urban Design and Development
______

Graduate (Fall)
(Same subject as11.301[J])
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4252
Lecture: TR9.30-11 (9-354)
______
Examines both the structure of cities and ways they can be changed. Includes historical forces that have produced cities, models of urban analysis, contemporary theories of urban design, implementation strategies. Core lectures supplemented by discussion sessions focusing on student work and field trips. Guest speakers present cases involving current projects illustrating the scope and methods of urban design practice.
D. Frenchman
No required or recommended textbooks

4.253[J] Urban Design Politics
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as11.302[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Examines ways urban design contributes to distribution of political power and resources in cities. Investigates the nature of relations between built form and political purposes through close study of a wide variety of situations where public sector design commissions and planning processes have been clearly motivated by political pressures. Lectures and discussions focus on specific case studies of 20th-century government-sponsored designs carried out under diverse regimes in the US, Europe, and elsewhere.
L. Vale

4.254[J] Real Estate Development Studio: Complex Urban Projects
______

Graduate (Spring)
(Same subject as11.303[J])
Prereq: Permission of instructor
Units: 6-0-12
______
Focuses on the synthesis of projects for the real estate development industry, including the integration of physical design and programming with finance and marketing. Interdisciplinary student teams analyze how to maximize value in large-scale, mixed use projects in the process of preparing professional development proposals, involving sites in US cities and internationally. Reviews emerging real estate products and innovative developments to provide a foundation for studio work. Two major projects are interspersed with lectures, field trips, and short sketch exercises. Integrates skills and knowledge in the MSRED program; also open to other students interested in real estate development.
D. Frenchman, P. Roth

4.255[J] Site and Environmental Systems Planning
______

Graduate (Spring)
(Same subject as11.304[J])
Prereq: Permission of instructor
Units: 6-0-9
______
Introduces a range of practical approaches involved in evaluating and planning sites within the context of natural and cultural systems. Develops the knowledge and skills to analyze and plan a site for development through exercises and an urban design project. Topics include land inventory, urban form, spatial organization of uses, parcelization, design of roadways, grading, utility systems, off-site impacts, and landscape architecture.
M. A. Ocampo

4.264[J] Advanced Seminar in Landscape and Urbanism
______

Graduate (Spring)
(Same subject as11.334[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Explores theories, practices, and emerging trends in the fields of landscape architecture and urbanism, such as systemic design, landscape urbanism, engineered nature, drosscapes, urban biodiversity, urban mobility, megaregions, and urban agriculture. Lectures, readings, and guest speakers present a wide array of multi-disciplinary topics, including current works from P-REX lab. Students conduct independent and group research that is future-oriented.
A. Berger

4.270 Innovation for Humanitarian Assistance and Disaster Relief
(New)
______

Graduate (Spring)
Prereq: None
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Explores innovative solutions for large-scale disaster relief and humanitarian assistance (HADR) efforts. Uses case studies and interactive exercises to provide an overview of HADR activities, including generalized goals, operating environments, response communities, and technical challenges. Hands-on exercises emphasize the importance of system-oriented, sustainable design. Topics include sensing, communications, power systems, data analysis and design.
M. Mazereeuw

4.280 Undergraduate Architecture Internship
______

Undergrad (IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Students work in an architect's office to gain experience, improve skills, and see the inner workings of an everyday architectural practice. Internships possible in all sizes of firms and in public and nonprofit agencies. During IAP, a full-time, 4-week internship is required; maximum IAP credit, 6 units.
Architecture Design Staff

4.287 Graduate Architecture Internship
______

Graduate (IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Work in an architect's office to gain experience, improve skills, and see the inner workings of an everyday architectural practice. Internships possible in all sizes of firms and in public and nonprofit agencies. During IAP, a full-time, 4-week internship is required; maximum IAP credit, 6 units.
Architecture Design Staff

4.288 Preparation for SMArchS Thesis
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4288
Design: M2-5 (1-132) or T EVE (4-7 PM) (1-242) or F9 (5-216) or TBA
______
Students select thesis topic, define method of approach, and prepare thesis proposal for SMArchS degree. Faculty supervision on an individual or group basis. Intended for SMArchS program students prior to registration for 4.ThG.
T. Nagakura, M. Dennis, M. Goulthorpe
No textbook information available

4.291 Independent Study in Architecture Studies
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.292 Independent Study in Architecture Studies
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

4.293 Independent Study in Architecture Studies
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.294 Independent Study in Architecture Studies
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual or group basis. Registration subject to prior arrangement for subject matter and supervision by staff.
Architecture Studies Staff
No required or recommended textbooks

4.299 Summer Research Topics
______

Graduate (Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Supplementary summer work on individual basis. Registration subject to prior arrangement for subject matter and supervision by staff.
Staff
No textbook information available

4.S20 Special Subject: Architecture Studies
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

4.S21 Special Subject: Architecture Studies
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
______

4.S22 Special Subject: Architecture Studies
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.S23 Special Subject: Architecture Studies
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.S24 Special Subject: Architecture Studies
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Seminar or lecture on a topic in architecture studies that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Architecture Staff

4.S25 Special Subject: Urban Housing
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in urban housing that is not covered in the regular architecture curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Architecture Staff

4.S26 Special Subject: City Form
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in city form that is not covered in the regular architecture curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Architecture Staff

4.S27 Special Subject: Urban Design
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in urban design that is not covered in the regular Architecture curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Architecture Staff


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Produced: 29-SEP-2016 06:37 AMFall 2016 Course 4: Architecture
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Course 4: Architecture
Fall 2016


Art, Culture and Technology

4.301 Introduction to Artistic Experimentation
______

Undergrad (Fall, Spring) HASS Arts
Prereq: None
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4301
Lecture: TR2-5 (E15-207)
______
Introduces artistic practice and critical visual thinking through three studio-based projects using different scales and mediafor instance, "Body Extension," "Shaping Time," Public Making," and/or 'Networked Cultures." Each project concludes with a final presentation and critique. Students explore sculptural, architectural, performative artistic methods; video and sound art; site interventions and strategies for artistic engagement in the public realm. Lectures, screenings, guest presentations, field trips, readings, and debates supplement studio practice. Also introduces students to the historic, cultural, and environmental forces affecting both the development of an artistic vision and the reception of a work of art. Limited to 20.
A. Aksamija
No required or recommended textbooks

4.302 Foundations in Art, Design, and Spatial Practices
______

Undergrad (Spring)
Prereq: 4.021 or 4.02A
Units: 3-3-6
______
Develops an introductory foundation in artistic practice and its critical analysis, and develops artistic approaches and methods by drawing analogies to architectural thinking, urbanism, and design practice. Covers how to communicate ideas and experiences on different scales and through two-dimensional, three-dimensional, and time-based media in new genres. Uses artistic methods that engage the public realm through spatial, sculptural, performative, and process-oriented practices. Instruction components include video screenings, guest lectures, visiting artist presentations, and field trips. Instruction and practice in written and oral communication provided. Enrollment limited; preference to Course 4 majors and minors.
A. Aksamija

4.307 Art, Architecture, and Urbanism in Dialogue
______

Undergrad (Fall)
(Subject meets with4.308)
Prereq: 4.301, 4.302, or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4307
Lecture: TR9.30-12.30 (E15-283A)
______
Initiates a dialogue between architecture, urbanism, and contemporary art by focusing on the work of practitioners who intertwine the three disciplines in a critical spatial practice. Investigates themes and works ranging from early modernist practices to the contemporary and research based. Lectures, screenings, readings, and discussions with guests and faculty contribute to the development of group and individual projects and their presentation. Additional work required of students taking graduate version. Limited to 20.
T. Putrih
No required or recommended textbooks

4.308 Art, Architecture, and Urbanism in Dialogue
______

Graduate (Fall)
(Subject meets with4.307)
Prereq: Permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4307
Lecture: TR9.30-12.30 (E15-283A)
______
Initiates a dialogue between architecture, urbanism, and contemporary art by focusing on the work of practitioners who intertwine the three disciplines in a critical spatial practice. Investigates themes and works ranging from early modernist practices to the contemporary and research based. Lectures, screenings, readings, and discussions with guests and faculty contribute to the development of group and individual projects and their presentation. Additional work required of students taking graduate version. Limited to 20.
T. Putrih
No required or recommended textbooks

4.312 Advanced Studio on the Production of Space
______

Undergrad (Fall) HASS Arts Can be repeated for credit
(Subject meets with4.313)
Prereq: 4.301, 4.302, or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4312
Lecture: MW9.30-12.30 (E15-001)
______
No required or recommended textbooks

4.313 Advanced Studio on the Production of Space
______

Graduate (Fall) Can be repeated for credit
(Subject meets with4.312)
Prereq: Permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4312
Lecture: MW9.30-12.30 (E15-001)
______
Introduces historical and contemporary spatial concepts from various cultures and geo-political settings, and examines how they relate to artistic process and production. Explores the relational qualities of spatial concepts and reflects on their producers and proponents; investigates the notion of utopian, dystopian and heterotopian space, inner and outer space, the void, the vacuum, the in-between, and "real" versus "virtual" space. Lectures, readings, screenings, presentations, and guest speakers from various disciplines support the development of individual and collective projects. Additional work required of students taking the graduate version. Limited to 20.
G. Urbonas, N. Bojic
No required or recommended textbooks

4.314 Advanced Workshop in Artistic Practice and Transdisciplinary Research
______

Undergrad (Spring) HASS Arts Can be repeated for credit
(Subject meets with4.315)
Prereq: 4.301, 4.302, or permission of instructor
Units: 3-3-6
______

4.315 Advanced Workshop in Artistic Practice and Transdisciplinary Research
______

Graduate (Spring) Can be repeated for credit
(Subject meets with4.314)
Prereq: Permission of instructor
Units: 3-3-6
______
Examines artistic practice as a form of critical inquiry and knowledge production. Offers opportunity to develop art as a means for addressing the social, cultural, and ecological consequences of technology, to build bridges between industry and culture, and to challenge the boundaries between public and private, and human and non-human. Provides instruction in evaluating models of experimentation, individual research, and collaboration with other disciplines in the arts, culture, science, and technology. Supports the development of individual and collective artistic research projects. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff

4.320 Introduction to Sound Creations
______

Undergrad (Spring) HASS Arts
(Subject meets with4.321)
Prereq: None
Units: 3-3-6
______
Develops a critical awareness of how sound art as a field for artistic exploration is performed, produced, and distributed. Explores contemporary and historical practices that emerge outside of purely musical environments and investigates specific compositional developments of post-war modernity and electro-acoustic music, as well as non-musical disciplines related to the psychophysics of hearing and listening. Lectures, screenings, readings, and discussions with guests and faculty contribute to the development of group and individual projects. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff

4.321 Introduction to Sound Creations
______

Graduate (Spring)
(Subject meets with4.320)
Prereq: None
Units: 3-3-6
______
Develops a critical awareness of how sound art as a field for artistic exploration is performed, produced, and distributed. Explores contemporary and historical practices that emerge outside of purely musical environments and investigates specific compositional developments of post-war modernity and electro-acoustic music, as well as non-musical disciplines related to the psychophysics of hearing and listening. Lectures, screenings, readings, and discussions with guests and faculty contribute to the development of group and individual projects. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff

4.322 Introduction to Three-Dimensional Art Work
______

Undergrad (Fall) HASS Arts
(Subject meets with4.323)
Prereq: None
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4322
Lecture: TR9.30-12.30 (E15-207)
______
Explores three-dimensional art work, including sculptures and installations, from design to model to finished piece. Addresses challenges associated with design and fabrication, process, context, and relationships between objects, the body, and physical or cultural environments. Lectures, screenings, field trips, readings, and debates supplement studio practice. Additional work required of students taking the graduate version. Limited to 20.
A. Aksamija
No required or recommended textbooks

4.323 Introduction to Three-Dimensional Art Work
______

Graduate (Fall)
(Subject meets with4.322)
Prereq: None
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4322
Lecture: TR9.30-12.30 (E15-207)
______
Explores three-dimensional art work, including sculptures and installations, from design to model to finished piece. Addresses challenges associated with design and fabrication, process, context, and relationships between objects, the body, and physical or cultural environments. Lectures, screenings, field trips, readings, and debates supplement studio practice. Additional work required of students taking the graduate version. Limited to 20.
A. Aksamija
No required or recommended textbooks

4.330 Introduction to Networked Cultures and Participatory Media
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Arts
(Subject meets with4.331)
Prereq: None
Units: 3-3-6
Subject Cancelled Subject Cancelled
______

4.331 Introduction to Networked Cultures and Participatory Media
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.330)
Prereq: None
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Provides an overview of participatory art practices, early net art, net activism, and current online practices in art and culture. Explores the cultural, social, and political impacts of mediated communication and examines how online communications have altered the way in which collaboration occurs, changes notions of authorship, and gives rise to collectives. Incorporates implementation, critique, and design exercises and experiments, developing skills in media literacy and communication. Lectures, screenings, readings, and discussions with guests and faculty lead to the development of group and individual projects. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff

4.332 Advanced Seminar in Networked Cultures and Participatory Media
______

Undergrad (Spring) HASS Arts
(Subject meets with4.333)
Prereq: 4.330 or permission of instructor
Units: 3-3-6
______
Provides skills in media literacy and communications necessary to create networked platforms and participatory media. Explores new and emergent critical platforms and strategies, such as independent and alternative media, hybrid TV, blogs, and other social media. Incorporates implementation, critique, and discussion of design exercises and experiments. Lectures, screenings, readings, and discussions with guests and faculty lead to the development of group and individual projects. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff

4.333 Advanced Seminar in Networked Cultures and Participatory Media
______

Graduate (Spring)
(Subject meets with4.332)
Prereq: 4.330, 4.331, or permission of instructor
Units: 3-3-6
______
Provides skills in media literacy and communications necessary to create networked platforms and participatory media. Explores new and emergent critical platforms and strategies, such as independent and alternative media, hybrid TV, blogs, and other social media. Incorporates implementation, critique, and discussion of design exercises and experiments. Lectures, screenings, readings, and discussions with guests and faculty lead to the development of group and individual projects. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff

4.341 Introduction to Photography and Related Media
______

Undergrad (Fall, Spring) HASS Arts
(Subject meets with4.342)
Prereq: None
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4341
Lecture: TR2-5 (E15-054)
______
No required or recommended textbooks

4.342 Introduction to Photography and Related Media
______

Graduate (Fall, Spring)
(Subject meets with4.341)
Prereq: Permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4341
Lecture: TR2-5 (E15-054)
______
Introduces history and contemporary practices in artistic photography through projects, lectures, artist visits, group discussions, readings, and field trips. Fosters visual literacy and aesthetic appreciation of photography/digital imaging, as well as critical awareness of how images in our culture are produced and constructed. Provides instruction in the fundamentals of different camera formats, film exposure and development, lighting, black and white darkroom printing, and digital imaging. Assignments allow for incorporation of a range of traditional and experimental techniques, development of technical skills, and personal exploration. Throughout the term, present and discuss projects in a critical forum. Additional work required of students taking the graduate version. Limited to 20.
L. Baladi
No required or recommended textbooks

4.344 Advanced Photography and Related Media
______

Undergrad (Fall, Spring) HASS Arts
(Subject meets with4.345)
Prereq: 4.341 or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4344
Lecture: TR EVE (7-10 PM) (E15-054)
______
Fosters critical awareness of how images in our culture are produced and constructed. Covers a range of experimental techniques and camera formats, advanced traditional and experimental black-and-white darkroom printing, and all aspects of digital imaging and output. Includes individual and group reviews, field trips, and visits from outside professionals. Topical focus changes each term; coursework centers on student-initiated project with emphasis on conceptual, theoretical, and technical development. Additional work required of students taking the graduate version. Equipment available for checkout. Limited to 20.
L. Baladi
No required or recommended textbooks

4.345 Advanced Photography and Related Media
______

Graduate (Fall, Spring) Can be repeated for credit
(Subject meets with4.344)
Prereq: 4.342 or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4344
Lecture: TR EVE (7-10 PM) (E15-054)
______
Fosters critical awareness of how images in our culture are produced and constructed. Covers a range of experimental techniques and camera formats, advanced traditional and experimental black-and-white darkroom printing, and all aspects of digital imaging and output. Includes individual and group reviews, field trips, and visits from outside professionals. Topical focus changes each term; coursework centers on student-initiated project with emphasis on conceptual, theoretical, and technical development. Additional work required of students taking the graduate version. Equipment available for checkout. Limited to 20.
L. Baladi
No required or recommended textbooks

4.352 Advanced Video and Related Media
______

Undergrad (Fall, Spring) HASS Arts
(Subject meets with4.353)
Prereq: 4.354 or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4352
Lecture: TR EVE (7-10 PM) (E15-070)
______
Introduces advanced strategies of image and sound manipulation, both technical and conceptual. Covers pre-production planning (storyboards and scripting), refinement of digital editing techniques, visual effects such as chroma-keying, post-production, as well as audio and sonic components. Context provided by regular viewings of contemporary video artworks and other audio-visual formats. Students work individually and in groups to develop skills in media literacy and communication. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff
No required or recommended textbooks

4.353 Advanced Video and Related Media
______

Graduate (Fall, Spring)
(Subject meets with4.352)
Prereq: 4.355 or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4352
Lecture: TR EVE (7-10 PM) (E15-070)
______
Introduces advanced strategies of image and sound manipulation, both technical and conceptual. Covers pre-production planning (storyboards and scripting), refinement of digital editing techniques, visual effects such as chroma-keying, post-production, as well as audio and sonic components. Context provided by regular viewings of contemporary video artworks and other audio-visual formats. Students work individually and in groups to develop skills in media literacy and communication. Additional work required of students taking the graduate version. Limited to 20.
Art, Culture and Technology Staff
No required or recommended textbooks

4.354 Introduction to Video and Related Media
______

Undergrad (Fall) HASS Arts
(Subject meets with4.355)
Prereq: None
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4354
Lecture: TR2-5 (E15-283A)
______
Textbooks (Fall 2016)

4.355 Introduction to Video and Related Media
______

Graduate (Fall)
(Subject meets with4.354)
Prereq: None
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4354
Lecture: TR2-5 (E15-283A)
______
Examines the technical and conceptual variables and strategies inherent in contemporary video art practice. Analyzes structural concepts of time, space, perspective, and sound within the art form. Building upon the historical legacy of film and other time-based image media, students render self-exploration, performance, social critique, and manipulation of raw experience into an aesthetic form. Emphasizes practical knowledge of lighting, video capturing and editing, and montage. Includes presentation and critique of student work, technical workshops, screenings, and readings with the objective of a final creative project. Additional work required of students taking the graduate version. Limited to 20.
C. Joskowicz
Textbooks (Fall 2016)

4.356 Cinematic Migrations
______

Undergrad (Fall) HASS Arts
(Subject meets with4.357)
Prereq: 4.301, 4.302, 4.354 or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4356
Lecture: TR2-5 (E15-070)
______
No required or recommended textbooks

4.357 Cinematic Migrations
______

Graduate (Fall) Can be repeated for credit
(Subject meets with4.356)
Prereq: 4.355 or permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4356
Lecture: TR2-5 (E15-070)
______
Explores ideas and contexts behind moving images through a multifaceted look at cinema's transmutations, emergence on local and national levels, and global migrations. Examines the transformation caused by online video, television, spatial installations, performances, dance, and many formats and portable devices, as well as the theory and context of film's categorization, dissemination, and analysis. Presentations, screenings, field trips, readings, visiting artists, and experimental transdisciplinary projects broaden the perception of present cinema. Additional work required of students taking the graduate version. Limited to 12.
R. Green
No required or recommended textbooks

4.361 Performance Art Workshop
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Arts
(Subject meets with4.362)
Prereq: 4.301, 4.302, or permission of instructor
Units: 3-3-6
Subject Cancelled Subject Cancelled
______

4.362 Performance Art Workshop
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.361)
Prereq: None
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Surveys performance in relation to media and to spatial structures imagined as settings for narrative movements, and uses video to explore the perception of sounds and images and how they are altered by various devices. Students design visual forms and performative actions, and make props or objects that embody aspects of their narratives. Activities include readings and screenings on the theoretical and historical background of performance art. Assignments lead to a final performance project. Additional work required of students taking graduate version. Limited to 20.
Art, Culture and Technology Staff

4.368 Studio Seminar in Public Art/Public Sphere
______

Undergrad (Spring) HASS Arts
(Subject meets with4.369)
Prereq: 4.301, 4.302, or permission of instructor
Units: 3-3-6
______
Focuses on the production of artistic interventions in public space outside of the gallery or museum context. Explores the variety of ideas, situations, objects, and materials that shape public space. Traditional forms of commemoration are examined in comparison to temporal and critical forms of public art and action. Historical models include the Russian Constructivists, the Situationists International, conceptual art, and contemporary interventionist tactics and artistic strategies. Assigned readings and discussions help students develop an initial concept for a publicly diffused project. Additional work required of students taking graduate version. Limited to 20.
Art, Culture and Technology Staff

4.369 Studio Seminar in Public Art/Public Sphere
______

Graduate (Spring)
(Subject meets with4.368)
Prereq: None
Units: 3-3-6
______
Focuses on the production of artistic interventions in public space outside of the gallery or museum context. Explores the variety of ideas, situations, objects, and materials that shape public space. Traditional forms of commemoration are examined in comparison to temporal and critical forms of public art and action. Historical models include the Russian Constructivists, the Situationists International, conceptual art, and contemporary interventionist tactics and artistic strategies. Assigned readings and discussions help students develop an initial concept for a publicly diffused project. Additional work required of students taking graduate version. Limited to 20.
A. Muntadas

4.373 Advanced Projects in Visual Arts
______

Undergrad (Spring) HASS Arts Can be repeated for credit
(Subject meets with4.374)
Prereq: 4.301, 4.302, or permission of instructor
Units: 3-3-6
______

4.374 Advanced Projects in Visual Arts
______

Graduate (Spring) Can be repeated for credit
(Subject meets with4.373)
Prereq: Permission of instructor
Units: 3-3-6
______
Investigates conceptual and formal issues in a variety of media. Explores issues of representation, interpretation, and meaning, and how they relate to historical, social, and cultural context. Additional work required of students taking graduate version. Limited to 20.
Art, Culture and Technology Staff

4.388 Preparation for SMACT Thesis
______

Graduate (Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-6
URL: architecture.mit.edu/subject/spring-2016-4388
______
Provides assistance to students as they select a thesis topic, develop a method of approach, prepare a proposal, and develop an outline for their thesis. Explores artistic practice as method of critical inquiry. Examines artists' writing and clarifies academic requirements and standards. Regular group meetings, including peer reviews, supplemented by independent study and individual conferences with faculty. Restricted to first-year SMACT students.
Art, Culture and Technology Staff
No textbook information available

4.389 Tutorial for SMACT Thesis
______

Graduate (Spring) Can be repeated for credit
Prereq: 4.388;Coreq: 4.THG
Units: 3-0-6
URL: architecture.mit.edu/subject/spring-2016-4389
______
Series of tutorials that includes regular presentations of student writing in group critiques and supports independent thesis research and development by providing guidance on research strategy and written presentation. Sessions supplemented by regular individual conferences with thesis committee members. Restricted to second-year SMACT students.
Art, Culture and Technology Staff

4.390 Art, Culture and Technology Studio
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4390
Lecture: MF2-5 (E15-001) +final
______
Explores the theory and criticism of intersections between art, culture, and technology in relation to contemporary artistic practice, critical design, and media. Students consider methods of investigation, documentation, and display and explore modes of communication across disciplines. Students develop projects in which they organize research methods and goals, engage in production, cultivate a context for their practice, and explore how to compellingly communicate, display, and document their work. Regular presentation and peer-critique sessions, as well as reviews involving ACT faculty and fellows, and external guest reviewers provide students with ample feedback as their projects develop. Restricted to SMACT students.
Fall:G. Urbonas
Spring:R. Green
No required or recommended textbooks

4.391 Independent Study in Art, Culture and Technology
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.392 Independent Study in Art, Culture and Technology
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

4.393 Independent Study in Art, Culture and Technology
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.394 Independent Study in Art, Culture and Technology
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual basis. Registration subject to prior arrangement for subject matter and supervision by staff.
Art, Culture and Technology Staff
No required or recommended textbooks

4.S30 Special Subject: Art, Culture and Technology
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

4.S31 Special Subject: Art, Culture and Technology
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
______

4.S32 Special Subject: Art, Culture and Technology
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
Subject Cancelled Subject Cancelled
______

4.S33 Special Subject: Art, Culture and Technology
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: WF9.30-12.30 (E15-283A)
______
Textbooks (Fall 2016)

4.S34 Special Subject: Art, Culture and Technology
______

Graduate (Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Seminar or lecture on a topic in visual arts that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Art, Culture & Technology Staff


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Produced: 29-SEP-2016 06:37 AMFall 2016 Course 4: Architecture
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Course 4: Architecture
Fall 2016


Building Technology

4.401 Environmental Technologies in Buildings
______

Undergrad (Fall)
(Subject meets with4.464)
Prereq: None
Units: 3-2-7
URL: http://architecture.mit.edu/subject/fall-2016-4401
Lecture: MW11-12.30 (1-277) Lab: F11 (1-150)
______
Introduction to the study of the thermal and luminous behavior of buildings. Examines the basic scientific principles underlying these phenomena and introduces students to a range of technologies and analysis techniques for designing comfortable indoor environments. Challenges students to apply these techniques and explore the role energy and light can play in shaping architecture. Additional work required of students taking the graduate version.
C. Reinhart
No textbook information available

4.411[J] D-Lab Schools: Building Technology Laboratory
______

Not offered academic year 2016-2017Undergrad (Fall) Institute Lab
(Same subject asEC.713[J])
Prereq: Physics I (GIR), Calculus I (GIR)
Units: 2-3-7
______
Focuses on the design, analysis, and application of technologies that support the construction of less expensive and better performing schools in developing countries. Prepares students to design or retrofit school buildings in partnership with local communities and NGOs. Strategies covered include daylighting, passive heating and cooling, improved indoor air quality via natural ventilation, appropriate material selection, and structural design. Investigations are based on application of engineering fundamentals, experiments and simulations. Case studies illustrate the role of technologies in reducing barriers to improved education.
L. K. Norford

4.42[J] Fundamentals of Energy in Buildings
______

Not offered academic year 2016-2017Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject as1.044[J],2.66[J])
Prereq: Physics I (GIR), Calculus II (GIR)
Units: 3-2-7
______
Design-based introduction to energy and thermo-sciences, with applications to sustainable, energy-efficient architecture and building technology. Covers introductory thermodynamics, air/water/vapor mixtures, and heat transfer. Studies leading order factors in building energy use. Includes several building design projects in which students creatively employ energy fundamentals and building energy use.
L. R. Glicksman

4.424[J] Modeling and Approximation of Thermal Processes
______

Graduate (Fall)
(Same subject as2.52[J])
Prereq: 2.51
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4424
Lecture: MW12.30-2 (5-217)
______
Provides instruction on how to model thermal transport processes in typical engineering systems such as those found in manufacturing, machinery, and energy technologies. Successive modules cover basic modeling tactics for particular modes of transport, including steady and unsteady heat conduction, convection, multiphase flow processes, and thermal radiation. Includes a creative design project executed by the students.
L. R. Glicksman
Textbooks (Fall 2016)

4.430 Daylighting and Solar Gain Control
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 4.464 or permission of instructor
Units arranged
______
Studies natural and electric lighting in an architectural context. Promotes the integration of occupant comfort, energy efficiency and daylight availability throughout the design process, with an emphasis on the role light can play in shaping architecture. Through group and individual projects, students practice design techniques, from rule of thumb simulations to high dynamic range photography and physical model building. Offered for 9 or 12 units.
C. Reinhart

4.431 Architectural Acoustics
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units arranged
______
Describes interactions between people and sound, indoors and outdoors, and uses this information to develop acoustical design criteria for architecture and planning. Principles of sound generation, propagation, and reception. Properties of materials for sound absorption, reflection, and transmission. Design implications for performance and gathering spaces. Use of computer modeling techniques.
Building Technology Staff

4.432 Modeling Urban Energy Flows for Sustainable Cities and Neighborhoods
______

Not offered academic year 2017-2018Undergrad (Spring)
(Subject meets with4.433)
Prereq: Permission of instructor
Units: 3-2-7
______

4.433 Modeling Urban Energy Flows for Sustainable Cities and Neighborhoods
______

Not offered academic year 2017-2018Graduate (Spring)
(Subject meets with4.432)
Prereq: Permission of instructor
Units: 3-2-4
______
Studies energy flows in and around groups of buildings from individual buildings to complete large-scale neighborhoods. Students use emerging digital techniques to analyze and influence building design interventions in relation to energy use for construction (embodied energy) and operation, access to daylight, and assessing walkability and outdoor comfort at the neighborhood scale. Additional work required of students taking the graduate version.
C. Reinhart

4.440[J] Building Structural Systems I
______

Undergrad (Spring) Rest Elec in Sci & Tech
(Same subject as1.056[J])
(Subject meets with4.462)
Prereq: Calculus II (GIR)
Units: 3-3-6
______
Introduces the design and behavior of large-scale structures and structural materials. Emphasizes the development of structural form and the principles of structural design. Presents design methods for timber, masonry, concrete and steel applied to long-span roof systems, bridges, and high-rise buildings. Includes environmental assessment of structural systems and materials. In laboratory sessions, students solve structural problems by building and testing simple models. Graduate and undergraduate students have separate lab sections.
J. Ochsendorf

4.444 Analysis of Historic Structures
______

Undergrad (Fall)
(Subject meets with1.574[J],4.445[J])
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4444
Lecture: W2-5 (1-242)
______
Textbooks (Fall 2016)

4.445[J] Analysis of Historic Structures
______

Graduate (Fall)
(Same subject as1.574[J])
(Subject meets with4.444)
Prereq: None
Units: 3-0-6
URL: http://architecture.mit.edu/subject/fall-2016-4444
Lecture: W2-5 (1-242)
______
Technical and historical study of structures in architecture and engineering. Focuses on the design and assessment of historic structures in masonry, timber, concrete, and metal. Course is driven by student research proposals. Previous student projects have researched Gothic flying buttresses, wooden covered bridges, Roman aqueducts, and iron train stations.
J. Ochsendorf
Textbooks (Fall 2016)

4.447[J] Design for Sustainability
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as1.819[J])
Prereq: Permission of instructor
Units: 2-0-4
Subject Cancelled Subject Cancelled
______
Presents thought processes and quantitative tools, including life-cycle assessment (LCA) and the LEED and ENVSION rating systems, applicable to integrated design of buildings and horizontal infrastructure with the goal of minimizing the waste of materials, energy, and water. Readings, lectures, site visits, and assignments encourage systematic thinking and interdisciplinary collaboration to make sustainable design a reality. Includes a team project of students' choice, such as a conceptual design of a sustainable new building, a "green" retrofit, or a comparative LCA.
J. Ochsendorf

4.450[J] Computational Structural Design and Optimization
______

Graduate (Fall)
(Same subject as1.575[J])
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4450
Lecture: F9-12 (9-354) +final
______
Research seminar focusing on cutting-edge applications of computation for creative, early-stage structural design and optimization for architecture. Incorporates computational design fundamentals, including problem parameterization and formulation; design space exploration strategies, including interactive, heuristic, and gradient-based optimization; and computational structural analysis methods, including the finite element method, graphic statics, and approximation techniques. Case studies introduce and investigate a range of historical and contemporary examples of structural optimization in theory and practice.
C. Mueller
No textbook information available

4.462 Building Structural Systems I
______

Graduate (Spring)
(Subject meets with1.056[J],4.440[J])
Prereq: Permission of instructor
Units: 3-2-4
URL: http://architecture.mit.edu/building-technology/subject/building-structural-systems-i
______
Introduces the design and behavior of large-scale structures and structural materials. Emphasizes the development of structural form and the principles of structural design. Introduces design methods for timber, masonry, concrete, and steel applied to long-span roof systems, bridges, and high-rise buildings. Includes environmental assessment of structural systems and materials. Laboratory to solve structural problems by building and testing simple models. Graduate and undergraduate students have separate lab sections.
J. Ochsendorf

4.463 Building Structural Systems II
______

Graduate (Fall)
Prereq: 4.440, 4.462, or permission of instructor
Units: 3-2-4
URL: http://architecture.mit.edu/subject/fall-2016-4463
Lecture: MW9.30-11 (1-150) Lab: W11-1 (5-233) +final
______
Addresses advanced structures, exterior envelopes, and contemporary production technologies. Continues the exploration of structural elements and systems, expanding to include more complex determinate, indeterminate, long-span, and high-rise systems. Topics include reinforced concrete, steel and engineered-wood design, and an introduction to tensile systems. The contemporary exterior envelope is discussed with an emphasis on the classification of systems, performance attributes, and analysis techniques, material specifications and novel construction technologies.
C. Mueller
No textbook information available

4.464 Environmental Technologies in Buildings
______

Graduate (Fall)
(Subject meets with4.401)
Prereq: None
Units: 3-2-4
URL: http://architecture.mit.edu/subject/fall-2016-4401
Lecture: MW11-12.30 (1-277) Lab: F11 (1-150) +final
______
Introduction to the study of the thermal and luminous behavior of buildings. Examines the basic scientific principles underlying these phenomena and introduces students to a range of technologies and analysis techniques for designing comfortable indoor environments. Challenges students to apply these techniques and explore the role energy and light can play in shaping architecture. Additional work required of students taking the graduate version.
C. Reinhart
No textbook information available

4.473 Design Workshop for a Sustainable Future
______

Graduate (Spring) Can be repeated for credit
Prereq: 4.151, 4.464; or permission of instructor
Units: 3-0-6
______
Focuses on strengthening the link between design and technology with an emphasis on sustainability concepts. Introduces theories behind resource-efficient built environments and how they can enhance the design process. Students explore ways to effectively integrate building performance goals, such as energy-efficiency, efficient material use, structural stability and occupant comfort into the design process. Limited to 16.
J. Ochsendorf

4.481 Building Technology Seminar
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-0-1
URL: http://architecture.mit.edu/subject/fall-2016-4481
Lecture: R3-5 (5-232)
______
Fundamental research methodologies and ongoing investigations in building tehnology to support the development of student research projects. Topics drawn from low energy building design and thermal comfort, building systems analysis and control, daylighting, structural design and analysis, novel building materials and construction techniques and resource dynamics. Organized as a series of two- and three-week sessions that consider topics through readings, discussions, design and analysis projects, and student presentations.
L. R. Glicksman, C. Mueller, J. Ochsendorf, C. Reinhart
No textbook information available

4.488 Preparation for S.M.B.T. Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4488
TBA.
______
Selection of thesis topic, definition of method of approach, and preparation of thesis proposal. Independent study supplemented by individual conference with faculty.
Building Technology Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

4.489 Preparation for Building Technology Ph.D. Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4489
TBA.
______
Selection of thesis topic, definition of method of approach, and preparation of thesis proposal. Independent study supplemented by individual conference with faculty.
Building Technology Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

4.491 Independent Study in Building Technology
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.492 Independent Study in Building Technology
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

4.493 Independent Study in Building Technology
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.494 Independent Study in Building Technology
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual basis. Registration subject to prior arrangement for subject matter and supervision by staff.
Building Technology Staff
No required or recommended textbooks

4.S40 Special Subject: Building Technology
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

4.S41 Special Subject: Building Technology
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
______

4.S42 Special Subject: Building Technology
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.S43 Special Subject: Building Technology
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.S44 Special Subject: Building Technology
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Seminar or lecture on a topic in building technology that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Building Technology Staff

4.S45 Special Subject: Building Construction
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in building construction that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Building Technology Staff

4.S46 Special Subject: Energy in Buildings
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in energy in buildings that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Building Technology Staff

4.S47 Special Subject: Architectural Lighting
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in architectural lighting that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Building Technology Staff

4.S48 Special Subject: Structural Design
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in structural design that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Architecture Building Technology Staff


left arrow|Architecture Design|Architecture Studies|Art, Culture and Technology|Building Technology|Computation|History, Theory and Criticism of Architecture and Art|Thesis and UROP|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 4: Architecture
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Course 4: Architecture
Fall 2016


Computation

4.500 Introduction to Design Computing
______

Undergrad (Fall)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4500
Lecture: TR9.30-11 (4-159)
______
Introduces 3-D CAD modeling to students with little or no experience in design or computation. Teaches surface, solid and mesh modeling techniques combined with a variety of modeling applications, from 3D printing to CNC fabrication and 3D rendering. Includes weekly modeling assignments leading up to a final project. Enrollment limited; preference to Course 4 majors and minors.
L. Sass
No required or recommended textbooks

4.501 Creative Design Prototyping
______

Undergrad (Spring)
Prereq: 4.500
Units: 2-2-8
______
Introduction to digital fabrication and online presentation as a single design process. Project-based class that integrates iterative design on paper with physical prototyping across many scales. Hands on learning of fabrication lab equipment integrated with design studio. It starts with machine learning through exercises quickly moving to a stepped design to production process: 3D printings, CNC machining and robotic finishing. The final product is an individually designed and fabricated functional piece of furniture. Preference to Course 4 majors and minors.
L. Sass

4.502 Advanced Visualization: Architecture in Motion Graphics
______

Undergrad (Fall)
(Subject meets with4.562)
Prereq: 4.500 or permission of instructor
Units: 3-2-7
URL: http://architecture.mit.edu/subject/fall-2016-4502
Lab: M EVE (7 PM) (5-216) Design: M12.30-3 (4-144) +final
______
Advanced projects in architectural visualization with an emphasis on the use of computer graphics animation and video production media. Workshop introduces advanced visualization software and teaches exploration of spatial expressions in motion graphics format. Students review and discuss selected literature and video materials on architecture and film. Additional work required of students taking the graduate version. Preference to Course 4 majors and minors.
T. Nagakura
No required or recommended textbooks

4.504 Design Scripting
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with4.564)
Prereq: 4.500
Units: 2-2-8
______
Introduces fundamental ideas of computer programming and demonstrates their application to the process of visual and spatial design. Teaches methods for algorithmically modeling visual and spatial forms, evaluating their conditions, building interface, and processing formal data for prototyping, manufacturing, rendering, and other design tools. Proceeds through a sequence of scripting exercises in application programming environments. Each exercise requires a student to articulate computational tasks in the context of a design, and to write codes that produce graphic solutions. Additional work required of students taking the graduate version.
T. Nagakura

4.507 Introduction to Building Information Modeling in Architecture
(New)
______

Undergrad (Spring)
(Subject meets with4.567)
Prereq: None
Units: 3-2-7
______
Addresses fundamental methods, theories, and practices that engage contemporary modeling tools in the context of architectural design. Introduces selected academic and professional topics through lectures, demonstrations, and assignments. Topics include parametric modeling, component types and assembly, prototyping, scripting, and simulations. Initiates intellectual explorations in the use of building information modeling in research projects and design practices. Additional work required of students taking graduate version.
T. Nagakura

4.511 Advanced Projects in Digital Fabrication
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
Independent projects in the study of digital fabrication as it relates to architecture design. Students propose a project within one of the following areas of investigation: new materials, software design for makers, fabrication based modeling, robotic fabrication.
L. Sass

4.517 Parametric and Building Information Modeling
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 4.500 or permission of instructor
Units: 3-2-7
______
Addresses professional applications of digital modeling in the development of contemporary construction systems and practical applications of geometry and digital modeling used to realize built complex forms. Surveys digitally-founded professional engineering, construction, and fabrication practices through case studies, shop visits, and on-campus and videoconference lectures. Includes modeling and making exercises, case studies, and a final project that addresses digital system design, analysis, and fabrication. Limited to 20.
Computation Staff

4.520 Visual Computing I
______

Undergrad (Spring)
(Subject meets with4.521)
Prereq: None
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduces a visual-perceptual, rule-based approach to design using shape grammars. Covers grammar fundamentals through lectures and in-class, exercises. Focuses on shape grammar applications, from stylistic analysis to creative design, through presentations of past applications and through short student exercises and projects. Presents computer programs for automating shape grammars. Additional work required of students taking graduate version.
T. Knight

4.521 Visual Computing I
______

Graduate (Spring)
(Subject meets with4.520)
Prereq: None
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Introduces a visual-perceptual, rule-based approach to design using shape grammars. Covers grammar fundamentals through lectures and in-class, exercises. Focuses on shape grammar applications, from stylistic analysis to creative design, through presentations of past applications and through short student exercises and projects. Presents computer programs for automating shape grammars. Additional work required of students taking graduate version.
T. Knight

4.522 Visual Computing II
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with4.523)
Prereq: 4.520 or permission of instructor
Units: 3-0-9
______

4.523 Visual Computing II
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.522)
Prereq: 4.520, 4.521 or permission of instructor
Units: 3-0-6
______
Introduces advanced topics in shape grammar theory and applications. Includes an introductory component on shape grammars for students new to the area. Discusses generalizations of the shape grammar formalism that provide alternative ways of computing and representing designs. These include parametric grammars and parametric design, parallel grammars, and color grammars. Presents material through lectures and in-class, applied exercises. Additional work required of graduate students.
T. Knight

4.540 Introduction to Shape Grammars I
______

Graduate (Fall)
Prereq: None
Units: 3-0-6
URL: http://architecture.mit.edu/subject/fall-2016-4540
Lecture: M9.30-12.30 (1-132)
______
No required or recommended textbooks

4.541 Introduction to Shape Grammars II
______

Graduate (Spring)
Prereq: 4.540
Units: 3-0-6
______
An in-depth introduction to shape grammars and their applications in architecture and related areas of design. Shapes in the algebras Ui j, in the algebras Vi j and Wi j incorporating labels and weights, and in algebras formed as composites of these. Rules and computations. Shape and structure. Designs.
G. Stiny

4.542 Background to Shape Grammars
______

Graduate (Spring) Can be repeated for credit
Prereq: 4.541 or permission of instructor
Units: 3-0-6
______
An advanced examination of the shape grammar formalism and its relationship to some key issues in a variety of other fields, including art and design, philosophy, history and philosophy of science, linguistics and psychology, literature and literary studies, logic and mathematics, and artificial intelligence. Student presentations and discussion of selected readings are encouraged. Topics vary from year to year. Can be repeated with permission of instructor.
G. Stiny

4.550 Computational Design Lab
______

Undergrad (Spring) Can be repeated for credit
(Subject meets with4.570)
Prereq: Permission of instructor
Units arranged
______

4.552 Workshop in Architectural Computation
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.553 Workshop in Architectural Computation
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Opportunity for exploration of a topic in computation through research-focused design projects or exercises. Registration subject to prior arrangement of topic and supervision by staff.
Computation Staff

4.557[J] City Science
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject asMAS.552[J])
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4557
Lecture: W2-5 (E15-359)
______
Focuses on architectural and mobility interventions that respond to changing patterns of living, working, and transport. Emphasizes mass-customized housing, autonomous parking, charging infrastructure, and shared-use networks of lightweight electric vehicles (LEVs). Students work in small teams and are lead by researchers from the Changing Places group. Projects focus on the application of these ideas to case study cities and may include travel. Invited guests from academia and industry participate. Repeatable for credit with permission of instructor.
K. Larson, R. Chin
No textbook information available

4.562 Advanced Visualization: Architecture in Motion Graphics
______

Graduate (Fall)
(Subject meets with4.502)
Prereq: Permission of instructor
Units: 3-2-7
URL: http://architecture.mit.edu/subject/fall-2016-4502
Lab: M EVE (7 PM) (5-216) Design: M12.30-3 (4-144) +final
______
Advanced projects in architectural visualization with an emphasis on the use of computer graphics animation and video production media. Introduces advanced visualization software and teaches exploration of spatial expressions in motion graphics format. Students review and discuss selected literature and video materials on architecture and film. Additional work required of students taking the graduate version.
T. Nagakura
No required or recommended textbooks

4.564 Design Scripting
______

Not offered academic year 2017-2018Graduate (Spring)
(Subject meets with4.504)
Prereq: Permission of instructor
Units: 2-2-8
______
Introduces fundamental ideas of computer programming and demonstrates their application to the process of visual and spatial design. Teaches methods for algorithmically modeling visual and spatial forms, evaluating their conditions, building interface, and processing formal data for prototyping, manufacturing, rendering, and other design tools. Proceeds through a sequence of scripting exercises in application programming environments. Each exercise requires a student to articulate computational tasks in the context of a design, and to write codes that produce graphic solutions. Additional work required of students taking the graduate version.
T. Nagakura

4.566 Advanced Projects in Digital Media
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 4.562, 4.564, or permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4566
Lecture: W EVE (5-7 PM) (7-304)
______
Develop independent projects in the study of digital media as it relates to architectural design. Students propose a project topic such as digital design tool, modeling and visualization, motion graphics, design knowledge representation and media interface.
T. Nagakura
No required or recommended textbooks

4.567 Introduction to Building Information Modeling in Architecture
(4.561)
______

Graduate (Spring)
(Subject meets with4.507)
Prereq: None
Units: 3-2-7
______
Addresses fundamental methods, theories, and practices that engage contemporary modeling tools in the context of architectural design. Introduces selected academic and professional topics through lectures, demonstrations, and assignments. Topics include parametric modeling, component types and assembly, prototyping, scripting, and simulations. Initiates intellectual explorations in the use of building information modeling in research projects and design practices. Additional work required of students taking graduate version.
T. Nagakura

4.569[J] Designing Interactions
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject asCMS.834[J])
(Subject meets withCMS.634)
Prereq: None
Units: 3-3-6
URL: http://architecture.mit.edu/subject/fall-2016-4569
Lecture: W10-1 (E15-335)
______
Explores the future of mobile interactions and pervasive computing, taking into consideration design, technological, social and business aspects. Discusses theoretical works on human-computer interaction, mobile media and interaction design, and covers research and design methods. Students work in multidisciplinary teams and participate in user-centric design projects aimed to study, imagine and prototype concepts illustrating the future of mobile applications and ubiquitous computing. Students taking graduate version complete additional assignments. Repeatable for credit with permission of instructor. Limited to 12.
F. Casalegno, T. Nagakura
No textbook information available

4.570 Computational Design Lab
______

Graduate (Spring) Can be repeated for credit
(Subject meets with4.550)
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/spring-2014-4570
______
Provides students with an opportunity to explore projects that engage real world problems concerning spatial design, technology, media, and society. In collaboration with industry partners and public institutions, students identify topical issues and problems, and also explore and propose solutions through the development of new ideas, theories, tools, and prototypes. Industry and academic collaborators act as a source of expertise, and as clients and critics of projects developed during the term. General theme of workshop varies by semester or year. Open to students from diverse backgrounds in architecture and other design-related areas. Additional work required of students taking graduate version.
Computation Staff

4.580 Inquiry into Computation and Design
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4580
Lecture: T9.30-12.30 (9-450A)
______
Explores the varied nature, history and practice of computation in design through lectures, readings, small projects, discussions, and guest visits by Computation group faculty and others. Topics may vary from year to year. Aims to help students develop a critical awareness of different approaches to and assumptions about computation in design beyond the specifics of techniques and tools, and to open avenues for further research.
T. Knight
No required or recommended textbooks

4.581 Proseminar in Computation
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9 [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4581
Lecture: T9.30-12.30 (5-232)
______
Introduction to traditions of research in design and computation scholarship.
G. Stiny
No required or recommended textbooks

4.582 Research Seminar in Computation
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 4.580 or permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4581
TBA.
______
In-depth presentations of current research in design and computation.
G. Stiny
No required or recommended textbooks

4.583 Forum in Computation
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of Instructor
Units: 3-0-0 [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4583
Lecture: W EVE (6-8 PM) (5-216)
______
Group discussions and presentation of ongoing graduate student research in the Computation program.
T. Knight
No textbook information available

4.584 Reading Seminar in Design and Computation
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4584
Subject Cancelled Subject Cancelled
______
Reading and discussion of particular topics in design and computation. Students lead discussions, make oral presentations, and prepare reviews of weekly readings.
T. Knight

4.587 SMArchS Computation Pre-Thesis Preparation
______

Graduate (Spring)
Prereq: 4.221 or permission of instructor
Units: 3-0-3 [P/D/F]
URL: architecture.mit.edu/subject/spring-2016-4587
______
Preliminary study in preparation for the thesis for the SMArchS degree in Computation. Topics include literature search, precedents examination, thesis structure and typologies, and short writing exercise.
T. Knight, T. Nagakura

4.589 Preparation for Design and Computation PhD Thesis
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4589
TBA.
______
Selection of thesis topic, definition of method of approach, and preparation of thesis proposal in computation. Independent study supplemented by individual conference with faculty.
Computation Staff
No textbook information available

4.591 Independent Study in Architectural Computation
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.592 Independent Study in Architectural Computation
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

4.593 Independent Study in Architectural Computation
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

4.594 Independent Study in Architectural Computation
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual basis. Registration subject to prior arrangement for subject matter and supervision by staff.
Computation Staff
No required or recommended textbooks

4.S50 Special Subject: Architectural Computation
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

4.S51 Special Subject: Architectural Computation
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
______

4.S52 Special Subject: Architectural Computation
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: R EVE (5-8 PM) (4-144)
______
No textbook information available

4.S53 Special Subject: Architectural Computation
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

4.S54 Special Subject: Architectural Computation
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Seminar or lecture on a topic in computation and design that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Computation Staff

4.S55 Special Subject: Digital Fabrication
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in computation and design that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
L. Sass, D. Smithwick

4.S56 Special Subject: Shape Grammars
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in computation and design that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
Computation Staff


left arrow|Architecture Design|Architecture Studies|Art, Culture and Technology|Building Technology|Computation|History, Theory and Criticism of Architecture and Art|Thesis and UROP|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 4: Architecture
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Course 4: Architecture
Fall 2016


History, Theory and Criticism of Architecture and Art

4.601 Introduction to Art History
______

Undergrad (Fall) HASS Arts
Prereq: None
Units: 3-2-7
URL: http://architecture.mit.edu/subject/fall-2016-4601
Lecture: TR2-3.30 (3-133) Recitation: W1 (5-216) or F1 (5-216) +final
______
Introduction to the history and interpretation of western art that explores painting, graphic arts and sculpture from the Renaissance to the present. Engages diverse methodological perspectives to examine changing conceptions of art and the artist, and to investigate the plural meaning of artworks within the larger contexts of culture and history. Subject includes trips to local museums.
D. Pullins
Textbooks (Fall 2016)

4.602 Modern Art and Mass Culture
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Arts Communication Intensive HASS
(Subject meets with4.652)
Prereq: None
Units: 4-0-8
______
Introduction to theories of modernism and postmodernism and their related forms (roughly 18th century to present) in art and design. Focuses on how artists use the tension between fine art and mass culture to critique both. Examines visual art in a range of genres, from painting to design objects and "relational aesthetics." Works of art are viewed in their interaction with advertising, caricature, comics, graffiti, television, fashion, "primitive" art, propaganda, and networks on the internet. Additional work required of students taking graduate version.
C. Jones

4.603 Understanding Modern Architecture
______

Undergrad (Fall) HASS Arts
(Subject meets with4.604)
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4603
Lecture: MW9.30-11 (4-153)
______
Examines modern architecture, art, and design in the context of the political, economic, aesthetic, and cultural changes that occurred in the twentieth century. Presents foundational debates about social and technological aspects of modern architecture and the continuation of those debates into contemporary architecture. Incorporates varied techniques of historical and theoretical analysis to interpret exemplary objects, buildings, and cities of modernity. Additional work required of students taking the graduate version. Preference to Course 4 majors and minors.
T. Hyde
Textbooks (Fall 2016)

4.604 Understanding Modern Architecture
______

Graduate (Fall)
(Subject meets with4.603)
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4603
Lecture: MW9.30-11 (4-153)
______
Examines modern architecture, art, and design in the context of the political, economic, aesthetic, and cultural changes that occurred in the twentieth century. Presents foundational debates about social and technological aspects of modern architecture and the continuation of those debates into contemporary architecture. Incorporates varied techniques of historical and theoretical analysis to interpret exemplary objects, buildings, and cities of modernity. Additional work required of students taking the graduate version. Preference to Course 4 majors.
T. Hyde
Textbooks (Fall 2016)

4.605 A Global History of Architecture
______

Undergrad (Spring) HASS Arts
(Subject meets with4.650)
Prereq: None
Units: 4-0-8
______
Provides an outline of the history of architecture and urbanism from ancient times to the early modern period. Analyzes buildings as the products of culture and in relation to the special problems of architectural design. Stresses the geopolitical context of buildings and in the process familiarizes students with buildings, sites and cities from around the world. Additional work required of graduate students.
M. Jarzombek

4.606 Visual Perception and Art
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Arts Communication Intensive HASS
Prereq: None
Units: 3-2-7
______
Introduces visual perception from neurological, cultural, and artistic vantage points. Examines aspects of visual culture ranging from body adornment to public spaces, and from logotypes to moving images. Topics range from ritual space to forensics to machine-aided vision (cameras, radar devices, robotic scanners). Designed to develop skills in visual analysis and interpretation through lectures, oral presentations, field trips, and written essays. Enrollment limited.
C. Jones

4.607 Thinking About Architecture: In History and At Present
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 4.645 or permission of instructor
Units arranged
______
Studies the interrelationship of theory, history, and practice. Looks at theory not as specialized discourse relating only to architecture, but as touching on many issues, whether they be cultural, aesthetic, philosophical, or professional. Topics and examples are chosen from a wide range of materials, from classical antiquity to today.
M. Jarzombek

4.608 Seminar in the History of Art and Architecture
______

Graduate (Spring)
(Subject meets with4.609)
Prereq: Permission of instructor
Units arranged
______
Examination of historical method in art and/or architecture, focusing on periods and problems determined by the research interest of the faculty member leading the seminar. Emphasizes critical reading and viewing and direct tutorial guidance. Additional work required of students taking the graduate version.
HTC Staff

4.609 Seminar in the History of Art and Architecture
______

Undergrad (Spring) HASS Arts
(Subject meets with4.608)
Prereq: Permission of instructor
Units: 3-0-9
______
Examination of historical method in art and/or architecture, focusing on periods and problems determined by the research interest of the faculty member leading the seminar. Emphasizes critical reading and viewing and direct tutorial guidance. Additional work required of students taking the graduate version.
HTC Staff

4.610 Civic Islamic Architecture
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Arts
(Subject meets with4.611)
Prereq: None
Units: 3-0-9
______

4.611 Civic Islamic Architecture
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.610)
Prereq: None
Units arranged
______
In-depth analysis of selected examples of architecture in the Islamic world from the 7th to the 21st century. Examines the effects of politics, culture, religion, technology, and fashion on the formation and development of Islamic architectural traditions and situates them diachronically and synchronically in world context. Additional work required of students taking the graduate version.
N. Rabbat

4.612 Islamic Architecture and the Environment
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
URL: http://architecture.mit.edu/subject/fall-2016-4612
Lecture: M2-5 (5-216) +final
______
Studies how Islamic architecture, landscape architecture, and urban planning reflect and transform environmental processes in various regions and climates of the Islamic world, from Andalusia to Southeast Asia, with an emphasis on South Asia, Central Asia, and the Middle East. Using systematic approaches to environmental data collection and analysis, examines strategies behind the design of selected architectural elements and landscape design types, ranging in scale from the fountain to the garden, courtyard, city, and agrarian region. Critically explores cultural interpretations of Islamic environmental design (e.g., paradise gardens), as they developed over time in ways that enrich, modify, or obscure their historical significance.
J. Wescoat
No textbook information available

4.614 Architecture in the Islamic World
______

Undergrad (Fall) HASS Arts
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4614
Lecture: TR11-12.30 (5-216)
______
Introduces the history of Islamic cultures that spans fourteen centuries and three continents - Asia, Africa, Europe - and recent developments in the United States. Studies a number of representative examples, from the House of the Prophet to the present, in conjunction with their urban, social, political, and intellectual environments. Presents Islamic architecture both as a full-fledged historical tradition and as a dynamic and interactive cultural catalyst that influenced and was influenced by the civilizations with which it came in contact.
N. Rabbat
Textbooks (Fall 2016)

4.616 Selected Topics on Culture and Architecture
______

Graduate (Spring)
Prereq: Permission of instructor
Units arranged
______
Seminar on how culture interacts with architecture. Analyzes architecture as a conveyor of messages that transcend stylistic, formal, and iconographic concerns to include an assessment of disciplinary, political, ideological, social, and cultural factors. Critically reviews methodologies and theoretical premises of studies on culture and meaning. Focuses on examples from Islamic history and establishes historical and theoretical frameworks for investigation.
N. Rabbat

4.617 Issues in Islamic Urbanism
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units arranged
______
Seminar on selected topics from the history of Islamic urbanism. Examines patterns of settlement, urbanization, development, and architectural production in various places and periods, ranging from the formative period in the 7th century to the new cities emerging today. Discusses the leading factors in shaping and transforming urban forms, design imperatives, cultural and economic structures, and social and civic attitudes. Critically analyzes the body of literature on Islamic urbanism. Research paper required.
N. Rabbat

4.619 Historiography of Islamic Architecture
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4619
Lecture: W2-5 (5-216)
______
Critical review of literature on Islamic art and architecture in the last two centuries. Analyzes the cultural, disciplinary, and theoretical contours of the field and highlights the major figures that have influenced its evolution. Challenges the tacit assumptions and biases of standard studies of Islamic art and architecture and addresses historiographic and critical questions concerning how knowledge of a field is defined, produced, and reproduced.
N. Rabbat
No textbook information available

4.621 Orientalism and Representation
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units arranged
______
Seminar on the politics of representation with special focus on Orientalist traditions in architecture, art, literature, and scholarship. Critically analyzes pivotal texts, projects, and artworks that reflected the encounters between the West and the Orient from Antiquity to the present. Discusses how political, ideological, and religious attitudes informed the construction and reproduction of Western knowledge about the Islamic world as well as revisionist Eastern self-representations. Research paper required.
N. Rabbat

4.622 Islamic Gardens and Geographies
(New)
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with4.623)
Prereq: Permission of Instructor
Units: 3-0-9
______
Seminar focuses on the historical geography of Islamic gardens, from Andalusia to Southeast Asia, with an emphasis on the Indian subcontinent. Critically engages evidence from archaeological, art historical, and cartographic sources, and explores strategies for generating integrative accounts of historical landscapes. Topics include gardens, cities, cultural landscapes, and political territories, along with their contemporary significance for cultural heritage conservation and design. Additional work required of graduate students. Limited to 15.
J. Wescoat

4.623 Islamic Gardens and Geographies
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.622)
Prereq: Permission of instructor
Units: 3-0-9
______
Seminar focuses on the historical geography of Islamic gardens, from Andalusia to Southeast Asia, with an emphasis on the Indian subcontinent. Critically engages evidence from archaeological, art historical, and cartographic sources, and explores strategies for generating integrative accounts of historical landscapes. Topics include gardens, cities, cultural landscapes, and political territories, along with their contemporary significance for cultural heritage conservation and design. Additional work required of graduate students. Limited to 15.
J. Wescoat

4.625[J] Water Planning, Policy, and Design
______

Graduate (Fall) Can be repeated for credit
(Same subject as11.378[J])
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4625
Lecture: T9-12 (1-375) +final
______
Focuses on water in environmental planning, policy, and design. Draws together faculty and students who are working on water-related research projects to develop and maintain a current perspective on the field from the site to metropolitan and international scales. Limited to 15.
J. Wescoat
No textbook information available

4.633 Locating Capitalism: Producing Early Modern Cities and Objects
______

Graduate (Spring)
Prereq: Permission of instructor
Units arranged
______
Explores what defines the parameters of an early modern profit economy in Europe. Discusses major interpretive frameworks that historically have guided scholarship on the period in architectural, art, and economic history. Traces the core themes of commodification, production, and consumption - analyzing the relevance of studies on pre- and early modern globalization - to the culture and time under consideration. Can be taken for 9 or 12 units.
L. Jacobi

4.634 Early Modern Architecture and Art
______

Graduate (Fall)
(Subject meets with4.635)
Prereq: None
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4634
Lecture: TR11-12.30 (3-133) +final
______
No textbook information available

4.635 Early Modern Architecture and Art
______

Undergrad (Fall) HASS Arts
(Subject meets with4.634)
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4634
Lecture: TR11-12.30 (3-133) +final
______
Presents a history, from the 14th through the early 17th century, of architectural practice and design, as well as visual culture in Europe with an emphasis on Italy. Topics include the production and reception of buildings and artworks; the significance of a reinvigorated interest in antiquity; and representation of the individual, the state, and other institutions.Examines a variety of interpretive methods. Graduate students are expected to complete additional assignments.
L. Jacobi
No required or recommended textbooks

4.640 Advanced Study in Critical Theory of Architecture
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4640
Lecture: T2-5 (5-216)
______
Seminar on a selected topic in critical theory. Requires original research and presentation of oral and written report.
L. Jacobi
No textbook information available

4.641 19th-Century Art
______

Undergrad (Spring) HASS Arts
(Subject meets with4.644)
Prereq: None
Units: 4-0-8
______

4.644 19th-Century Art
______

Graduate (Spring)
(Subject meets with4.641)
Prereq: None
Units arranged
______
Survey of visual culture from the late 18th century to 1900 with an emphasis on Western Europe and its global points of contact. Topics include art and revolution, empire and its image, mythologies of the artist, gender and representation, public exhibitions, the dealer/critic system, and the emergence of the avant-garde. Strikes a balance between historical and contemporary critical perspectives to assess art's engagement with social and political experience of modernity. Additional work required of students taking the graduate version.
K. Smentek

4.645 Selected Topics in Architecture: 1750 to the Present
______

Graduate (Spring)
Prereq: 4.210 or permission of instructor
Units: 3-0-6
______
General study of modern architecture as a response to important technological, cultural, environmental, aesthetic, and theoretical challenges after the European Enlightenment. Focus on the theoretical, historiographic, and design approaches to architectural problems encountered in the age of industrial and post-industrial expansion across the globe, with specific attention to the dominance of European modernism in setting the agenda for the discourse of a global modernity at large. Explores modern architectural history through thematic exposition rather than as simple chronological succession of ideas.
A. Dutta

4.646 Advanced Study in the History of Modern Architecture and Urbanism
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
______
Seminar in a selected topic in the history of modern architecture and urbanism. Oral presentations and research paper required.
T. Hyde

4.647 Technopolitics, Culture, Intervention
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 4.645 or permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4647
Lecture: W2-5 (1-371)
______
Examines the manner in which key theories of technology have influenced architectural and art production in terms of their "humanizing" claims. Students test theories of technology on the grounds of whether technology is good or bad for humans. Limited to 15; preference to MArch students.
A. Dutta
No required or recommended textbooks

4.648[J] Resonance: Sonic Experience, Science, and Art
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Arts
(Same subject as21A.507[J])
(Subject meets with4.649[J],21A.519[J])
Prereq: None
Units: 3-0-9
______
Examines the sonic phenomena and experiences that motivate scientific, humanistic, and artistic practices. Explores the aesthetic and technical aspects of how we hear; measure or describe vibrations; record, compress, and distribute resonating materials; and how we ascertain what we know about the world through sound. Although the focus is on sound as an aesthetic, social, and scientific object, the subject also investigates how resonance is used in the analysis of acoustics, architecture, and music theory. Students make a sonic artifact or research project as a final requirement. Students taking graduate version complete additional assignments.
S. Helmreich, C. Jones

4.649[J] Resonance: Sonic Experience, Science, and Art
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as21A.519[J])
(Subject meets with4.648[J],21A.507[J])
Prereq: None
Units: 3-0-9
______
Examines the sonic phenomena and experiences that motivate scientific, humanistic, and artistic practices. Explores the aesthetic and technical aspects of how we hear; measure or describe vibrations; record, compress, and distribute resonating materials; and how we ascertain what we know about the world through sound. Although the focus is on sound as an aesthetic, social, and scientific object, the subject also investigates how resonance is used in the analysis of acoustics, architecture, and music theory. Students make a sonic artifact or research project as a final requirement. Students taking graduate version complete additional assignments.
S. Helmreich, C. Jones

4.650 A Global History of Architecture
(New)
______

Graduate (Spring)
(Subject meets with4.605)
Prereq: None
Units: 4-0-8
______
Provides an outline of the history of architecture and urbanism from ancient times to the early modern period. Analyzes buildings as the products of culture and in relation to the special problems of architectural design. Stresses the geopolitical context of buildings and in the process familiarizes students with buildings, sites and cities from around the world. Additional work required of graduate students.
M. Jarzombek

4.651 Art Since 1940
______

Undergrad (Spring) HASS Arts
Prereq: None
Units: 3-0-9
______
Critical examination of major developments in European, Asian, and American art from 1940 to the present. Surveys the mainstream of art production but also examines marginal phenomena (feminism, identity politics, AIDS activism, net art) that come to change the terms of arts engagements with civic culture. Visits to area art museums and writing assignments develop skills for visual analysis and critical writing.
C. Jones

4.652 Modern Art and Mass Culture
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.602)
Prereq: None
Units arranged
______
Introduction to theories of modernism and postmodernism and their related forms (roughly 18th century to present) in art and design. Focuses on how artists use the tension between fine art and mass culture to critique both. Examines visual art in a range of genres, from painting to design objects and "relational aesthetics." Works of art are viewed in their interaction with advertising, caricature, comics, graffiti, television, fashion, "primitive" art, propaganda, and networks on the internet. Additional work required of students taking the graduate version.
C. Jones

4.657 Design: The History of Making Things
(New)
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: None
Units: 5-0-7
______
Examines themes in the history of design, with emphasis on Euro-American theory and practice in their global contexts. Addresses the historical design of communications, objects, and environments as meaningful processes of decision-making, adaptation, and innovation. Critically assesses the dynamic interaction of design with politics, economics, technology, and culture in the past and at present.
T. Hyde, K. Smentek

4.661 Theory and Method in the Study of Architecture and Art
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4661
Lecture: M11-2 (5-216)
______
Studies theoretical and historiographical works pertaining to the fields of art and architectural history. Members of seminar pursue work designed to examine their own presuppositions and methods. Open only to PhD candidates and other advanced students.
M. Jarzombek
No required or recommended textbooks

4.670 Nationalism, Internationalism, and Globalism in Modern Art
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with4.671)
Prereq: None
Units arranged
4.670: URL: http://architecture.mit.edu/subject/spring-2016-4670
______

4.671 Nationalism, Internationalism, and Globalism in Modern Art
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with4.670)
Prereq: 4.601 or permission of instructor
Units: 3-1-8
URL: http://architecture.mit.edu/subject/spring-2016-4670
______
Studies how international modernism interacted with the concept of "nation" and how contemporary discourses concerning globalism changes that dynamic. Looks at how art uses and critiques globalization on various levels. Seminar attendance and visits to art museums required. Research paper required of students taking the graduate version.
C. Jones

4.672 Installation Art
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with4.673)
Prereq: None
Units arranged
______

4.673 Installation Art
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with4.672)
Prereq: 4.601 or permission of instructor
Units: 3-0-9
______
Focuses on a specific genre of contemporary art that produces environments or room-sized immersive forms rather than portable "art objects." Installation art is viewed from a historical perspective, as a rejection of the modernist aesthetic of purity and the neutral white gallery space. Its corollary in site-specific art is explored in relation to previous exhibition models such as natural history displays or merchandising conventions. Graduate students will be expected to produce a final research paper.
C. Jones

4.675 Collect, Classify, Consume
______

Graduate (Spring) Can be repeated for credit
Prereq: None
Units arranged
______
Historical study of collecting from the Renaissance to the present. Addresses the practices of collecting and display at the both the individual and institutional level, and analyzes their social, aesthetic, scientific, political and economic dimensions. Specific themes vary from year to year. Offered for 9 or 12 units. May be repeated for credit with permission of instructor.
K. Smentek

4.677 Advanced Study in the History of Art
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
______
Seminar in a selected topic in the history of art, with a particular emphasis on developments from the 18th century to the present. Oral presentations and research paper required. Offered for 9 or 12 units.
K. Smentek

4.683 Preparation for HTC Qualifying Paper
(New)
______

Graduate (Fall, Spring)
Prereq: Permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4683
TBA.
______
Required of doctoral students in HTC as a prerequisite for work on the doctoral dissertation. The qualifying paper is a scholarly article fit to be published in a peer-reviewed journal that is the result of research in the history, theory and criticism of architecture and art. Topic may not be in the area of the proposed thesis. Work is done in consultation with HTC faculty, in accordance with the HTC PhD Degree Program Guidelines. Restricted to HTC PhD students.
HTC Staff
No textbook information available

4.684 Preparation for HTC Major Exam
(New)
______

Graduate (Fall, Spring)
Prereq: permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4684
TBA.
______
Required of doctoral students in HTC as a prerequisite for work on the doctoral dissertation. The Major Exam covers a historically broad area of interest and includes components of history, historiography, and theory. Preparation for the exam will focus on four or five themes agreed upon in advance by the student and the examiner, and are defined by their area of teaching interest. Work is done in consultation with HTC faculty, in accordance with the HTC PhD Degree Program Guidelines. Restricted to HTC PhD students.
HTC Staff
No textbook information available

4.685 Preparation for HTC Minor Exam
(New)
______

Graduate (Fall, Spring)
Prereq: permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4685
TBA.
______
Required of doctoral students in HTC as a prerequisite for work on the doctoral dissertation. The Minor Exam focuses on a specific area of specialization through which the student might develop their particular zone of expertise. Work is done in consultation with HTC faculty, in accordance with the HTC PhD Degree Program Guidelines. Restricted to HTC PhD students.
HTC Staff
No textbook information available

4.686 SMArchS AKPIA Pre-Thesis Preparation
______

Graduate (Fall, Spring)
Prereq: 4.221; 4.619 or 4.621
Units: 0-1-2 [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4686
TBA.
______
Preliminary study in preparation for the thesis for the SMArchS degree in the Aga Khan Program for Islamic Architecture. Topics include literature search, precedents examination, thesis structure and typologies, and short writing exercise.
N. Rabbat, J. Wescoat
No required or recommended textbooks

4.687 SMArchS HTC Pre-Thesis Preparation
______

Graduate (Fall, Spring)
Prereq: 4.221, 4.661
Units: 0-1-2 [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4687
TBA.
______
Preliminary study in preparation for the thesis for the SMArchS degree in History, Theory and Criticism. Topics include literature search, precedents examination, thesis structure and typologies, and short writing exercise.
HTC Staff
No required or recommended textbooks

4.689 Preparation for History, Theory, and Criticism - Ph.D. Thesis
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
URL: http://architecture.mit.edu/subject/fall-2016-4689
TBA.
______
Required for doctoral students in HTC as a prerequisite for work on the doctoral dissertation. Prior to candidacy, doctoral students are required to write and orally defend a proposal laying out the scope of their thesis, its significance, a survey of existing research and literature, the methods of research to be adopted, a bibliography and plan of work. Work is done in consultation with HTC Faculty, in accordance with the HTC PhD Degree Program guidelines. Restricted to HTC PhD students.
HTC Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

4.691 Independent Study in the History, Theory, and Criticism of Architecture and Art
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Supplementary work on individual or group basis. Registration subject to prior arrangement for subject matter and supervision by staff.
HTC Staff
No required or recommended textbooks

4.692 Independent Study in the History, Theory, and Criticism of Architecture and Art
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual or group basis. Registration subject to prior arrangement for subject matter and supervision by staff.
HTC Staff
No required or recommended textbooks

4.693 Independent Study in the History, Theory, and Criticism of Architecture and Art
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Supplementary work on individual basis. Registration subject to prior arrangement for subject matter and supervision by staff.
HTC Staff
No required or recommended textbooks

4.694 Independent Study in the History, Theory, and Criticism of Architecture and Art
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Supplementary work on individual basis. Registration subject to prior arrangement for subject matter and supervision by staff.
HTC Staff
No required or recommended textbooks

4.S60 Special Subject: History, Theory and Criticism of Architecture and Art
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______
Seminar or lecture on a topic in the history, theory and criticism of architecture and art that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
HTC Staff

4.S61 Special Subject: History, Theory and Criticism of Architecture and Art
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged [P/D/F]
______
Seminar or lecture on a topic in the history, theory and criticism of architecture and art that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
HTC Staff

4.S62 Special Subject: History, Theory and Criticism of Architecture and Art
______

Graduate (Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in the history, theory and criticism of architecture and art that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
HTC Staff

4.S63 Special Subject: History, Theory and Criticism of Architecture and Art
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in the history, theory and criticism of architecture and art that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
HTC Staff

4.S64 Special Subject: History, Theory and Criticism of Architecture and Art
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Seminar or lecture on a topic in the history, theory and criticism of architecture and art that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
HTC Staff

4.S65 Special Subject: Advanced Study in Islamic Architecture
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in Islamic or non-western architecture that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports, varying at the discretion of the instructor.
HTC Staff

4.S66 Special Subject: History, Theory and Criticism of Art
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in the history, theory and criticism of art that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
HTC Staff

4.S67 Special Subject: Study in Modern Art
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: F10-1 (5-216)
______
Seminar or lecture on a topic in the history, theory and criticism of modern art that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
C. Jones, R. Uchill
No required or recommended textbooks

4.S68 Special Subject: Study in Modern Architecture
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4s68
Lecture: W9.30-12.30 (5-216)
______
Seminar or lecture on a topic in the history, theory and criticism of modern architecture that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
M. Jarzombek
No textbook information available

4.S69 Special Subject: Advanced Study in the History of Urban Form
______

Graduate (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Seminar or lecture on a topic in the history, theory and criticism of urban form that is not covered in the regular curriculum. Requires original research and presentation of oral and written reports and/or design projects, varying at the discretion of the instructor.
HTC Staff


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Course 4: Architecture
Fall 2016


Thesis and UROP


Graduate Subjects

Preparatory subjects for thesis are listed within each of the disciplinary headings of the subject listing.

4.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research and writing of thesis; to be arranged by the student with supervising committee.
Staff
Textbooks arranged individually


Undergraduate Subjects

4.119 Preparation for Undergraduate Architecture Design Thesis
______

Undergrad (Fall)
Prereq: 4.024
Units: 2-0-10
URL: http://architecture.mit.edu/subject/fall-2016-4119
Lecture: F10
______
Selection of thesis topic, defining method of approach, and preparation of thesis proposal for BSA degree in architecture. Weekly class meeting as well as individual conference with faculty.
J. Lamere
No textbook information available

4.THT[J] Thesis Research Design Seminar
______

Undergrad (Fall) Can be repeated for credit
(Same subject as11.THT[J])
Prereq: None
Units: 3-0-9
Lecture: F12-3 (9-217)
______
Designed for students writing a thesis in Urban Studies and Planning or Architecture. Develop research topics, review relevant research and scholarship, frame research questions and arguments, choose an appropriate methodology for analysis, and draft introductory and methodology sections.
C. Abbanat
No required or recommended textbooks

4.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 4.THT or 4.119
Units arranged
TBA.
______
Program of thesis research leading to the writing of an SB thesis, to be arranged by the student and an appropriate MIT faculty member. Intended for seniors. 12 units recommended.
Architecture Staff
Textbooks arranged individually

4.UR Undergraduate Research in Design
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually

4.URG Undergraduate Research in Design
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Research and project activities, which cover the range represented by the various research interests and projects in the department. Students who wish a letter grade option for their work must register for 4.URG.
L. Sass
Textbooks arranged individually


left arrow|Architecture Design|Architecture Studies|Art, Culture and Technology|Building Technology|Computation|History, Theory and Criticism of Architecture and Art|Thesis and UROP|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 5: Chemistry
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Course 5: Chemistry
Fall 2016


5.00[J] Energy Technology and Policy: From Principles to Practice
______

Graduate (Spring)
(Same subject as6.929[J],10.579[J],22.813[J])
Prereq: None
Units: 3-0-6
______
Develops analytical skills to lead a successful technology implementation with an integrated approach that combines technical, economical and social perspectives. Considers corporate and government viewpoints as well as international aspects, such as nuclear weapons proliferation and global climate issues. Discusses technologies such as oil and gas, nuclear, solar, and energy efficiency. Limited to 100.
J. Deutch

5.03 Principles of Inorganic Chemistry I
______

Undergrad (Spring)
Prereq: 5.12
Units: 5-0-7
______
Presents principles of chemical bonding and molecular structure, and their application to the chemistry of representative elements of the periodic system.
A. Radosevich, Y. Surendranath

5.04 Principles of Inorganic Chemistry II
______

Undergrad (Fall)
Prereq: 5.03
Units: 4-0-8
Lecture: MWF9 (2-105) Recitation: F12 (8-205) or F1 (8-205)
______
Systematic presentation of the chemical applications of group theory. Emphasis on the formal development of the subject and its applications to the physical methods of inorganic chemical compounds. Against the backdrop of electronic structure, the electronic, vibrational, and magnetic properties of transition metal complexes are presented and their investigation by the appropriate spectroscopy described.
M. Dinca, Y. Surendranath
Textbooks (Fall 2016)

5.05 Principles of Inorganic Chemistry III
______

Graduate (Fall)
Prereq: 5.03,Coreq: 5.04
Units: 2-0-4
Lecture: TR8.30-10 (8-205)
______
Principles of main group (s and p block) element chemistry with an emphasis on synthesis, structure, bonding, and reaction mechanisms.
C. C. Cummins
No textbook information available

5.061 Principles of Organometallic Chemistry
______

Graduate (Spring); first half of term
Prereq: 5.03
Units: 2-0-4
______
A comprehensive treatment of organometallic compounds of the transition metals with emphasis on structure, bonding, synthesis, and mechanism.
R. Schrock

5.062 Principles of Bioinorganic Chemistry
______

Graduate (Fall)
Prereq: 5.03
Units: 3-0-9
Lecture: TR10-11.30 (2-105)
______
Delineates principles that form the basis for understanding how metal ions function in biology. Includes the choice, uptake and assembly of metal-containing units; metal-induced folding of biomolecules; control of metal ion concentrations in cells; electron-transfer chemistry; atom and group transfer chemistry; protein tuning of metal properties; and applications to diagnosis and treatment of disease. Introduces additional topics to expose students to exciting new advances in the field, such as medicinal application of inorganic chemistry; multi-component enzyme systems (e.g.,nitrogenase, hydrogenase, and photosystem II); and metalloprotein engineering and design (e.g., the conversion by mutagenesis of existing metalloprotein scaffolds to achieve novel functions).
S. Lippard
Textbooks (Fall 2016)

5.063 Organometallic Compounds in Catalytic Reactions
______

Not offered academic year 2017-2018Graduate (Spring); first half of term
Prereq: 5.061
Units: 2-0-4
______
An exploration of organometallic chemistry from the perspective of catalytic reactions in organic and polymer chemistry.
R. Schrock

5.067 Crystal Structure Refinement
______

Graduate (Fall)
Prereq: 5.068, 5.069, or permission of instructor
Units: 2-3-1
Lecture: W2-4 (4-253) Lab: F1-4 (4-253)
______
Practical aspects of crystal structure determination from data collection strategies to data reduction and basic and advanced refinement problems of organic and inorganic molecules.
P. Mueller
Textbooks (Fall 2016)

5.068 Physical Inorganic Chemistry
______

Graduate (Spring); second half of term
Prereq: 5.03, 5.04
Units: 3-0-3
______
Discusses the physical methods used to probe the electronic and geometric structures of inorganic compounds, with additional techniques employed in the characterization of inorganic solids and surfaces. Includes vibrational spectroscopy, solid state and solution magnetochemical methods, Mössbauer spectroscopy, electron paramagnetic resonance spectroscopy, electrochemical methods, and a brief survey of surface techniques. Applications to current research problems in inorganic and solid-state chemistry.
M. Dinca

5.069 Crystal Structure Analysis
______

Graduate (Spring); first half of term
Prereq: 5.03, 5.04
Units: 2-0-4
______
Introduction to X-ray crystallography: symmetry in real and reciprocal space, space and Laue groups, geometry of diffraction, structure factors, phase problem, direct and Patterson methods, electron density maps, structure refinement, crystal growth, powder methods, limits of diffraction methods, structure data bases.
P. Mueller

5.07[J] Biological Chemistry I
______

Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject as20.507[J])
Prereq: 5.12
Units: 5-0-7
Credit cannot also be received for7.05
Lecture: MWF9 (4-370) Recitation: MW1 (36-372) or MW2 (36-372) or TR10 (36-144) or TR11 (36-144) +final
______
Chemical and physical properties of the cell and its building blocks. Structures of proteins and principles of catalysis. The chemistry of organic/inorganic cofactors required for chemical transformations within the cell. Basic principles of metabolism and regulation in pathways, including glycolysis, gluconeogenesis, fatty acid synthesis/degradation, pentose phosphate pathway, Krebs cycle and oxidative phosphorylation, DNA replication, and transcription and translation.
E. Nolan, A. Klibanov
Textbooks (Fall 2016)

5.08[J] Biological Chemistry II
______

Undergrad (Spring)
(Same subject as7.08[J])
(Subject meets with7.80)
Prereq: 5.12; 5.07 or 7.05
Units: 4-0-8
______
More advanced treatment of biochemical mechanisms that underlie biological processes. Topics include macromolecular machines such as the ribosome, the proteosome, fatty acid synthases as a paradigm for polyketide synthases and non-ribosomal polypeptide synthases, and polymerases. Emphasis is on experimental methods used to unravel these processes and how these processes fit into the cellular context and coordinate regulation.
E. Nolan

5.111 Principles of Chemical Science
______

Undergrad (Fall, Spring) Chemistry
Prereq: None
Units: 5-0-7
Credit cannot also be received for3.091,5.112,CC.5111,ES.3091,ES.5111,ES.5112
Lecture: MWF12 (10-250) Recitation: TR10 (36-112, 36-156) or TR11 (36-112, 4-159) or TR12 (4-159, 4-149, 36-112, 35-310, 36-144) or TR1 (36-144) or TR2 (4-145, 36-155, 36-112) or TR3 (4-145, 36-155) +final
______
Introduction to chemistry, with emphasis on basic principles of atomic and molecular electronic structure, thermodynamics, acid-base and redox equilibria, chemical kinetics, and catalysis. Introduction to the chemistry of biological, inorganic, and organic molecules.
Fall:M. Shoulders, T. Van Voorhis
Spring:M. Bawendi, M. Hong
Textbooks (Fall 2016)

5.112 Principles of Chemical Science
______

Undergrad (Fall) Chemistry
Prereq: None
Units: 5-0-7
Credit cannot also be received for3.091,5.111,CC.5111,ES.3091,ES.5111,ES.5112
Lecture: MWF11 (32-123) Recitation: TR11 (1-273) or TR12 (1-273, 13-4101) or TR2 (36-153, 26-204) +final
______
Introduction to chemistry for students with an unusually strong background in chemistry. Knowledge of calculus equivalent to 18.01 is recommended. Emphasis on basic principles of atomic and molecular electronic structure, thermodynamics, acid-base and redox equilibria, chemical kinetics, and catalysis. Applications of basic principles to problems in metal coordination chemistry, organic chemistry, and biological chemistry.
R. Schrock, S. Ceyer
Textbooks (Fall 2016)

5.12 Organic Chemistry I
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Chemistry (GIR)
Units: 5-0-7
Credit cannot also be received forCC.512
Lecture: MWF12 (32-123) Recitation: MW2 (36-156) or MW3 (36-156) or TR10 (8-205) or TR11 (8-205) or TR12 (36-372, 36-153) or TR1 (36-372, 36-153) or TR2 (36-372) or TR11 (4-265) or MW2 (26-302) +final
______
Introduction to organic chemistry. Development of basic principles to understand the structure and reactivity of organic molecules. Emphasis on substitution and elimination reactions and chemistry of the carbonyl group. Introduction to the chemistry of aromatic compounds.
Fall:J. Johnson, P. Ruiz-Castillo
Spring:R. L. Danheiser, P. Ruiz-Castillo
Textbooks (Fall 2016)

5.13 Organic Chemistry II
______

Undergrad (Fall)
Prereq: 5.12
Units: 5-0-7
Lecture: MWF12 (32-141) Recitation: MW2 (36-112) or MW3 (36-112) or TR10 (36-372) or TR11 (36-372, 13-3101) or TR1 (13-4101) or TR2 (13-4101) +final
______
Focuses on synthesis, structure determination, mechanism, and the relationships between structure and reactivity. Selected topics illustrate the role of organic chemistry in biological systems and in the chemical industry.
M. Movassaghi
Textbooks (Fall 2016)

5.24[J] Archaeological Science
______

Undergrad (Spring) HASS Social Sciences
(Same subject as3.985[J],12.011[J])
Prereq: Chemistry (GIR) or Physics I (GIR)
Units: 3-1-5
______
Pressing issues in archaeology as an anthropological science. Stresses the natural science and engineering methods archaeologists use to address these issues. Reconstructing time, space, and human ecologies provides one focus; materials technologies that transform natural materials to material culture provide another. Topics include 14C dating, ice core and palynological analysis, GIS and other remote sensing techniques for site location, soil micromorphology and site formation, sourcing of metal artifacts, and microstructural and mechanical analyses of cementitious materials used in ancient monumental buildings.
H. N. Lechtman

5.301 Chemistry Laboratory Techniques
______

Undergrad (IAP)
Prereq: Chemistry (GIR), permission of instructor
Units: 1-4-1 [P/D/F]
URL: http://chemistry.mit.edu/freshmen-pre-freshmen/chemistry-lab-techniques-5301
______
Practical training in basic chemistry laboratory techniques. Intended to provide freshmen with the skills necessary to undertake original research projects in chemistry. Freshmen only. Enrollment limited.
J. Dolhun

5.310 Laboratory Chemistry
______

Undergrad (Fall, Spring) Institute Lab
Prereq: None.Coreq: 5.12
Units: 2-8-2
Safety lecture mandatory. 9/7 or 9/8 at 1 pm room TBA. Lecture: TR12 (4-370) Lab: MW1-5 (4-430) or TR1-5 (4-430)
______
Introduces experimental chemistry for students who are not majoring in Course 5. Principles and applications of chemical laboratory techniques, including preparation and analysis of chemical materials, measurement of pH, gas and liquid chromatography, visible-ultraviolet spectrophotometry, infrared spectroscopy, kinetics, data analysis, and elementary synthesis. Enrollment limited.
J. Dolhun
Textbooks (Fall 2016)

5.35 Introduction to Experimental Chemistry
______

Undergrad (Fall, Spring) Institute Lab Can be repeated for credit
(Subject meets with5.35U)
Prereq: See module descriptions
Units arranged
URL: http://chemistry.mit.edu/urieca/urieca-module-signup-form-535535u
Select 4, 8 or 12 units. Safety lecture mandatory. 9/7 or 9/8 at 1 pm room TBA. Lecture: TR12 (4-153) Lab: MW1-5 (4-430) or TR1-5 (4-430)
______
This 12-unit subject consists of 3 modules, which may be taken during different terms. Modules and prerequisites are as follows:
Module 1 (Prereq: 5.111, 5.112 or 3.091) Survey of spectroscopy.
Module 2 (Prereq: 5.111, 5.112 or 3.091; Module 1) Synthesis of coordination compounds and kinetics.
Module 3 (Prereq: 5.111, 5.112 or 3.091; 5.12, Module 2) Fabrication of a polymeric light emitting device.
Enrollment limited; preference to Course 5 majors.
R. Field (Module 1), Y. Surendranath, M. Twardowski (Module 2), T. Swager (Module 3)
No textbook information available

5.35U Introduction to Experimental Chemistry
______

Undergrad (Fall, Spring) Can be repeated for credit
(Subject meets with5.35)
Prereq: See module descriptions under subject 5.35
Units arranged
URL: http://chemistry.mit.edu/urieca/urieca-module-signup-form-535535u
Select 4, 8 or 12 units. Safety lecture mandatory. 9/7 or 9/8 at 1 pm room TBA. Lecture: TR12 (4-153) Lab: MW1-5 (4-430) or TR1-5 (4-430)
______
For students who might not take all modules of 5.35. Consult department when choosing a version of 5.35. See description for 5.35. May be taken for 8 or 4 units and repeated for credit up to a total of 12 units.
R. W. Field (Module 1), Y. Surendranath, M. Twardowski (Module 2), T. Swager (Module 3)
No textbook information available

5.36 Biochemistry and Organic Laboratory
______

Undergrad (Fall, Spring) Can be repeated for credit
(Subject meets with5.36U)
Prereq: See module descriptions
Units arranged
URL: http://chemistry.mit.edu/urieca/urieca-module-signup-536536u
Select 4, 8 or 12 units. Safety lecture mandatory. 11/1 at 1 pm room 4-231. Lecture: TR12 (4-231) Lab: MW1-5 (4-430) or TR1-5 (4-430)
______
This 12-unit subject consists of 3 modules, which may be taken during different terms. Instruction and practice in the written and oral presentation of experimental results provided. Modules and prerequisites are as follows:
Module 4 Spring (Prereq: 5.07 or 7.05, Module 2 or 5.310, Module 5) Expression and Purification of Enzyme Mutants. Must be taken simultaneously with Module 5.
Module 5 Spring (Prereq: 5.07 or 7.05, Module 2 or 5.310, Module 4) Kinetics of Enzyme Inhibition. Must be taken simultaneously with Module 4.
Module 6 Fall (Prereq: 5.12, Module 2 or 5.310, 5.13) Organic Structure Determination.
Enrollment limited; preference to Course 5 majors.
Fall:R. L. Danheiser (Module 6)
Spring:B. Pentelute (Modules 4 & 5)
Textbooks (Fall 2016)

5.36U Biochemistry and Organic Laboratory
______

Undergrad (Fall, Spring) Can be repeated for credit
(Subject meets with5.36)
Prereq: See module descriptions under subject 5.36
Units arranged
URL: http://chemistry.mit.edu/urieca/urieca-module-signup-536536u
Select 4, 8 or 12 units. Safety lecture mandatory. 11/1 at 1 pm room 4-231. Lecture: TR12 (4-231) Lab: MW1-5 (4-430) or TR1-5 (4-430)
______
For students who might not take all modules of 5.36. Consult department when choosing a version of 5.36. See description for 5.36. May be taken for 8 or 4 units and repeated for credit up to a total of 12 units.
Fall:R. L. Danheiser (Module 6)
Spring:B. Pentelute (Modules 4 & 5)
Textbooks (Fall 2016)

5.37 Organic and Inorganic Laboratory
______

Undergrad (Fall, Spring) Can be repeated for credit
(Subject meets with5.37U)
Prereq: See module descriptions
Units arranged
URL: http://chemistry.mit.edu/urieca/urieca-module-signup-537537u
Select 4, 8 or 12 units. Safety lecture mandatory. 9/7 or 9/8 at 1 pm room TBA. Lecture: TR12 (4-231) Lab: MW1-5 (4-430) or TR1-5 (4-430)
______
This 12-unit subject consists of 3 modules, which may be taken during different terms. Modules and prerequisites are as follows:
Module 7 Spring (Prereq: 5.13, Module 6) Continuous Flow Chemistry: Sustainable Conversion of Reclaimed Vegetable Oil into Biodiesel.
Module 8 Fall (Prereq: 5.03, Module 2) Chemistry of Renewable Energy.
Module 9 Fall (Prereq: 5.03, Module 6, 5.61) Dinitrogen Cleavage.
Enrollment limited; preference to Course 5 majors.
Fall:Y. Surendranath (Module 8); C. C. Cummins (Module 9)
Spring:T. Jamison (Module 7)
No textbook information available

5.37U Organic and Inorganic Laboratory
______

Undergrad (Fall, Spring) Can be repeated for credit
(Subject meets with5.37)
Prereq: See module descriptions under subject 5.37
Units arranged
URL: http://chemistry.mit.edu/urieca/urieca-module-signup-537537u
Select 4, 8 or 12 units. Safety lecture mandatory. 9/7 or 9/8 at 1 pm room TBA. Lecture: TR12 (4-231) Lab: MW1-5 (4-430) or TR1-5 (4-430)
______
For students who might not take all modules of 5.37. Consult department when choosing a version of 5.37. See description for 5.37. May be taken for 8 or 4 units and repeated for credit up to a total of 12 units.
Fall:Y. Surendranath (Module 8); C. C. Cummins (Module 9)
Spring:T. Jamison (Module 7)
No textbook information available

5.38 Biological and Physical Chemistry Laboratory
______

Undergrad (Spring) Can be repeated for credit
Prereq: See module descriptions
Units arranged
URL: http://chemistry.mit.edu/urieca/urieca-module-signup-538
______
This 12-unit subject consists of 3 modules, which may be taken during different terms. Instruction and practice in the written and oral presentation of experimental results provided. Modules and prerequisites are as follows:
Module 10 (Prereq: 5.61, Module 6) Quantum Dots.
Module 11 (Prereq: 5.61, 5.07 or 7.05, Module 5) Time Resolved Molecular Spectroscopy.
Module 12 (Prereq: 5.07 or 7.05, Module 6)Fast Flow Peptide and Protein Synthesis.
Enrollment limited; preference to Course 5 majors.
M. G. Bawendi (Module 10), G. Schlau-Cohen (Module 11), B. Pentelute (Module 12)

5.43 Advanced Organic Chemistry
______

Undergrad (Fall)
Prereq: 5.13
Units: 4-0-8
Credit cannot also be received for5.53
Lecture: TR9.30-11 (4-257) Recitation: F11 (4-257) or F1 (4-257) +final
______
Reaction mechanisms in organic chemistry: methods of investigation, relation of structure to reactivity, and reactive intermediates. Photochemistry and organometallic chemistry, with an emphasis on fundamental reactivity, mechanistic studies, and applications in organic chemistry.
T. Swager
Textbooks (Fall 2016)

5.44 Organometallic Chemistry
______

Graduate (Spring); first half of term
Prereq: 5.43, 5.47, 5.061, or permission of instructor
Units: 2-0-4
______
Examination of the most important transformations of organotransition-metal species. Emphasizes basic mechanisms of their reactions, structure-reactivity relationships, and applications in synthesis.
K. Khan

5.45 Heterocyclic Chemistry
______

Graduate (Spring); second half of term
Prereq: 5.511, 5.53
Units: 2-0-4
______
Provides an introduction to the chemistry of heterocyclic compounds. Surveys synthesis and reactivity of the major classes of heterocyclic organic compounds. Discusses the importance of these molecules in the pharmaceutical and other industries.
S. Buchwald

5.46 NMR Spectroscopy and Organic Structure Determination
______

Graduate (Spring); first half of term
Prereq: 5.43
Units: 2-0-4
______
Applications of 1-D and 2-D1H and13C NMR spectroscopy to organic structure determination.
J. H. Simpson

5.47 Tutorial in Organic Chemistry
______

Graduate (Fall); partial term
Prereq: 5.43, permission of instructor
Units: 2-0-4 [P/D/F]
Ends Sep 30. Lecture: MWF9-11 (18-278, 18-578, 4-251)
______
Systematic review of basic principles concerned with the structure and transformations of organic molecules. Problem-solving workshop format. The program is intended primarily for first-year graduate students with a strong interest in organic chemistry. Meets during the month of September.
R. L. Danheiser
Textbooks (Fall 2016)


left arrow|5.00-5.4999|5.50-5.999, plus UROP and Theses|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 5: Chemistry
Registrar Home | Registrar Search:
 
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Home | Subject Search | Help | Symbols Help | Pre-Reg Help | Final Exam Schedule
 

Course 5: Chemistry
Fall 2016


5.511 Synthetic Organic Chemistry I
______

Graduate (Fall); partial term
Prereq: 5.43
Units: 3-0-9
Begins Oct 3. Lecture: MWF8.30-10 (4-159)
______
Introduction to the design of syntheses of complex organic compounds.
R. L. Danheiser
Textbooks (Fall 2016)

5.512 Synthetic Organic Chemistry II
______

Graduate (Spring); second half of term
Prereq: 5.511
Units: 2-0-4
______
General methods and strategies for the synthesis of complex organic compounds.
Staff

5.52 Advanced Biological Chemistry
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-2-8
Lecture: TR2.30-4.30 (8-119) Lab: TR1-5 (BEGINS OCT 31) (4-465)
______
Concepts and methods of biochemistry, with emphasis on quantitative aspects of problem analysis and fundamentals of experimental methods. Intended for first-year graduate students with a strong interest in biological chemistry.
A. M. Klibanov
No textbook information available

5.53 Molecular Structure and Reactivity
______

Graduate (Fall); partial term
Prereq: 5.13, 5.60
Units: 3-0-6
Credit cannot also be received for5.43
Begins Oct 3. Lecture: MWF10 (4-149)
______
Reaction mechanisms in organic chemistry: methods of investigation, relation of structure to reactivity, and reactive intermediates.
J. Van Humbeck
Textbooks (Fall 2016)

5.54[J] Frontiers in Chemical Biology
______

Graduate (Fall)
(Same subject as7.540[J],20.554[J])
Prereq: 5.13, 5.07, 7.06, permission of instructor
Units: 2-0-4
Lecture: R8.30-10 (4-231)
______
Introduction to current research at the interface of chemistry, biology, and bioengineering. Topics include imaging of biological processes, metabolic pathway engineering, protein engineering, mechanisms of DNA damage, RNA structure and function, macromolecular machines, protein misfolding and disease, metabolomics, and methods for analyzing signaling network dynamics. Lectures are interspersed with class discussions and student presentations based on current literature.
M. Shoulders
No textbook information available

5.56 Molecular Structure and Reactivity II
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: Permission of Instructor
Units: 2-0-4
______
Application of physical principles and methods to contemporary problems of interest in organic chemistry.
J. Johnson

5.561 Chemistry in Industry
______

Graduate (Spring); second half of term
Prereq: 5.03; 5.07 or 7.05; 5.13
Units: 2-0-4 [P/D/F]
______
Examination of recent advances in organic, biological, and inorganic and physical chemical research in industry. Taught in seminar format with participation by scientists from industrial research laboratories.
R. L. Danheiser

5.60 Thermodynamics and Kinetics
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR), Chemistry (GIR)
Units: 5-0-7
Lecture: MWF10 (4-370) Recitation: MW12 (36-372) or TR11 (36-153, 36-156) or TR12 (36-156, 2-146) or TR1 (2-146) or TR2 (2-146) +final
______
Equilibrium properties of macroscopic systems. Basic thermodynamics: state of a system, state variables. Work, heat, first law of thermodynamics, thermochemistry. Second and third law of thermodynamics: entropy and free energy, including the molecular basis for these thermodynamic functions. Phase equilibrium and properties of solutions. Chemical equilibrium of reactions in gas and solution phases. Rates of chemical reactions. Special attention to thermodynamics related to global energy issues.
Fall:M. Bawendi, A. Shalek
Spring:R. Field, A. Willard
Textbooks (Fall 2016)

5.61 Physical Chemistry
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Physics II (GIR), Calculus II (GIR), Chemistry (GIR)
Units: 5-0-7
Lecture: MWF10 (2-105) Recitation: MW12 (4-159) or TR11 (56-180) +final
______
Introductory quantum chemistry; particles and waves; wave mechanics; atomic structure and the Periodic Table; valence and molecular orbital theory; molecular structure; and photochemistry.
R. Field, M. Hong
Textbooks (Fall 2016)

5.62 Physical Chemistry
______

Undergrad (Spring)
Prereq: 5.60, 5.61
Units: 4-0-8
______
Elementary statistical mechanics; transport properties; kinetic theory; solid state; reaction rate theory; and chemical reaction dynamics.
S. Ceyer, J. Cao

5.64[J] Frontiers of Interdisciplinary Science in Human Health and Disease
______

Graduate (Spring)
(Same subject asHST.539[J])
Prereq: 5.13, 5.60; 5.07 or 7.05
Units: 3-0-9
______
Introduces major principles, concepts, and clinical applications of biophysics, biophysical chemistry, and systems biology. Emphasizes biological macromolecular interactions, biochemical reaction dynamics, and genomics. Discusses current technological frontiers and areas of active research at the interface of basic and clinical science. Provides integrated, interdisciplinary training and core experimental and computational methods in molecular biochemistry and genomics.
A. Shalek

5.68[J] Kinetics of Chemical Reactions
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as10.652[J])
Prereq: 5.62, 10.37, or 10.65
Units: 3-0-6
URL: http://web.mit.edu/10.652/www/
Lecture: TR11-12.30 (56-114)
______
Experimental and theoretical aspects of chemical reaction kinetics, including transition-state theories, molecular beam scattering, classical techniques, quantum and statistical mechanical estimation of rate constants, pressure-dependence and chemical activation, modeling complex reacting mixtures, and uncertainty/ sensitivity analyses. Reactions in the gas phase, liquid phase, and on surfaces are discussed with examples drawn from atmospheric, combustion, industrial, catalytic, and biological chemistry.
W. H. Green
Textbooks (Fall 2016)

5.697[J] Quantum Chemical Simulation
______

Undergrad (Fall)
(Same subject as10.437[J])
(Subject meets with5.698[J],10.637[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (14-0637)
______
Addresses both the theory and application of first-principles computer simulations methods (i.e., quantum, chemical, or electronic structure), including Hartree-Fock theory, density functional theory, and correlated wavefunction methods. Covers enhanced sampling, ab initio molecular dynamics, and transition-path-finding approaches as well as errors and accuracy in total and free energies. Discusses applications such as the study and prediction of properties of chemical systems, including heterogeneous, molecular, and biological catalysts (enzymes), and physical properties of materials. Students taking graduate version complete additional assignments.
H. J. Kulik
Textbooks (Fall 2016)

5.698[J] Quantum Chemical Simulation
______

Graduate (Fall)
(Same subject as10.637[J])
(Subject meets with5.697[J],10.437[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (14-0637)
______
Addresses both the theory and application of first-principles computer simulations methods (i.e., quantum, chemical, or electronic structure), including Hartree-Fock theory, density functional theory, and correlated wavefunction methods. Covers enhanced sampling, ab initio molecular dynamics, and transition-path-finding approaches as well as errors and accuracy in total and free energies. Discusses applications such as the study and prediction of properties of chemical systems, including heterogeneous, molecular, and biological catalysts (enzymes), and physical properties of materials. Students taking graduate version complete additional assignments.
H. J. Kulik
Textbooks (Fall 2016)

5.70[J] Statistical Thermodynamics
______

Graduate (Fall)
(Same subject as10.546[J])
Prereq: 5.60 or permission of instructor
Units: 3-0-9
Lecture: MW8.30-10 (4-231)
______
Develops classical equilibrium statistical mechanical concepts for application to chemical physics problems. Basic concepts of ensemble theory formulated on the basis of thermodynamic fluctuations. Examples of applications include Ising models, lattice models of binding, ionic and non-ionic solutions, liquid theory, polymer and protein conformations, phase transition, and pattern formation. Introduces computational techniques with examples of liquid and polymer simulations.
A. Willard, B. Zhang
Textbooks (Fall 2016)

5.72 Statistical Mechanics
______

Graduate (Spring); second half of term
Not offered regularly; consult department
Prereq: 5.70, 5.73, 18.075
Units: 2-0-4
______
Principles and methods of statistical mechanics. Classical and quantum statistics, grand ensembles, fluctuations, molecular distribution functions, and other topics in equilibrium statistical mechanics. Topics in thermodynamics and statistical mechanics of irreversible processes.
J. Cao

5.73 Introductory Quantum Mechanics I
______

Graduate (Fall)
Prereq: 5.61, 8.03, 18.03
Units: 3-0-9
Lecture: TR9.30-11 (1-150)
______
Presents the fundamental concepts of quantum mechanics: wave properties, uncertainty principles, Schrodinger equation, and operator and matrix methods. Includes applications to one-dimensional potentials (harmonic oscillator), three-dimensional centrosymetric potentials (hydrogen atom), and angular momentum and spin. Approximation methods include WKB, variational principle, and perturbation theory.
R. G. Griffin
Textbooks (Fall 2016)

5.74 Introductory Quantum Mechanics II
______

Graduate (Spring)
Prereq: 5.73
Units: 3-0-9
______
Time-dependent quantum mechanics and spectroscopy. Topics include perturbation theory, two-level systems, light-matter interactions, relaxation in quantum systems, correlation functions and linear response theory, and nonlinear spectroscopy.
K. Nelson, G. Schlau-Cohen

5.78 Biophysical Chemistry Techniques
______

Not offered academic year 2017-2018Graduate (Spring); first half of term
(Subject meets with7.71)
Prereq: 5.07 or 7.05
Units: 2-0-4
URL: http://web.mit.edu/5.78/www/
______
Presents principles of macromolecular crystallography that are essential for structure determinations. Topics include crystallization, diffraction theory, symmetry and space groups, data collection, phase determination methods, model building, and refinement. Discussion of crystallography theory complemented with exercises such as crystallization, data processing, and model building. Meets with 7.71 when offered concurrently. Enrollment limited.
C. Drennan, T. Schwartz

5.80 Advanced Topics of Current Special Interest
______

Graduate (Fall, Spring)
Prereq: 5.61 or 8.04; 18.03
Units: 3-0-9
TBA.
______
Advanced topics of current special interest.
Staff
No textbook information available

5.891 Independent Study in Chemistry for Undergraduates
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No textbook information available

5.892 Independent Study in Chemistry for Undergraduates
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Program of independent study under direction of Chemistry faculty member. May not substitute for required courses for the Chemistry major or minor.
Staff
No textbook information available

5.90 Problems in Chemistry
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Directed research and study of special chemical problems. For Chemistry graduate students only.
R. W. Field
No textbook information available

5.913 Seminar in Organic Chemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-1 [P/D/F]
Lecture: R EVE (4-6 PM) (6-120)
______
Discusses current journal publications in organic chemistry by graduate students and staff members.
R. L. Danheiser
No textbook information available

5.921 Seminar in Biological Chemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-1 [P/D/F]
Lecture: M EVE (4-6 PM) (4-270)
______
Discusses topics of current interest in biological chemistry by graduate students and staff.
M. Shoulders
No textbook information available

5.931 Seminar in Physical Chemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 5.60
Units: 2-0-1 [P/D/F]
Lecture: T EVE (4-6 PM) (6-120)
______
Discusses topics of current interest in physical chemistry by staff members and students.
A. Willard
No textbook information available

5.941 Seminar in Inorganic Chemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 5.03
Units: 2-0-1 [P/D/F]
Lecture: W EVE (4-6 PM) (4-370)
______
Discusses current research in inorganic chemistry by graduate students and staff.
S. Lippard
No textbook information available

5.95[J] Teaching College-Level Science and Engineering
______

Graduate (Fall)
(Same subject as1.95[J],7.59[J],8.395[J],18.094[J])
(Subject meets with2.978)
Prereq: None
Units: 2-0-2 [P/D/F]
URL: https://wikis.mit.edu/confluence/pages/viewpage.action?pageId=110876412
Lecture: R9-11 (4-149)
______
Participatory seminar focuses on the knowledge and skills necessary for teaching science and engineering in higher education. Topics include theories of adult learning; course development; promoting active learning, problemsolving, and critical thinking in students; communicating with a diverse student body; using educational technology to further learning; lecturing; creating effective tests and assignments; and assessment and evaluation. Students research and present a relevant topic of particular interest. Appropriate for both novices and those with teaching experience.
J. Rankin
No textbook information available

5.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of a PhD thesis; to be arranged by the student and an appropriate MIT faculty member.
R. W. Field
Textbooks arranged individually

5.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of original research under supervision of a chemistry faculty member, culminating with the preparation of a thesis. Ordinarily requires equivalent of two terms of research with chemistry department faculty member.
Staff
Textbooks arranged individually

5.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Program of research to be arranged by the student and a departmental faculty member. Research can be applied toward undergraduate thesis.
C. C. Cummins
Textbooks arranged individually

5.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Program of research to be arranged by the student and a departmental faculty member. May be taken for up to 12 units per term, not to exceed a cumulative total of 48 units. A 10-page paper summarizing research is required.
C. C. Cummins
Textbooks arranged individually


left arrow|5.00-5.4999|5.50-5.999, plus UROP and Theses|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 6: Electrical Engineering and Computer Science
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Course 6: Electrical Engineering and Computer Science
Fall 2016


Basic Undergraduate Subjects

6.00 Introduction to Computer Science and Programming
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: None
Units: 3-7-2
Lecture: MW3 (26-100) Lab: TBA +final
______
Introduction to computer science and programming for students with little or no programming experience. Students learn how to program and how to use computational techniques to solve problems. Topics include software design, algorithms, data analysis, and simulation techniques. Assignments are done using the Python programming language. Meets with 6.0001 first half of term and 6.0002 second half of term. Credit cannot also be received for 6.0001 or 6.0002. Final given during final exam week.
J. V. Guttag
Textbooks (Fall 2016)

6.0001 Introduction to Computer Science Programming in Python
______

Undergrad (Fall, Spring); first half of term
Prereq: None
Units: 2-3-1
Ends Oct 21. Lecture: MW3 (26-100) Recitation: F10 (36-112, 36-153) or F11 (36-112, 36-153) or F12 (36-153) or F1 (36-153) or F2 (36-153) or F3 (36-153) or F12 (36-112) or F1 (36-112) or F2 (36-112) or F3 (36-112) or F1 (36-156)
______
Introduction to computer science and programming for students with little or no programming experience. Students develop skills to program and use computational techniques to solve problems. Topics include the notion of computation, Python, simple algorithms and data structures, testing and debugging, and algorithmic complexity. Combination of 6.0001 and 6.0002 counts as REST subject. Final given in the seventh week of the term.
J. V. Guttag
Textbooks (Fall 2016)

6.0002 Introduction to Computational Thinking and Data Science
______

Undergrad (Fall, Spring); second half of term
Prereq: 6.0001 or permission of instructor
Units: 2-3-1
Begins Oct 24. Lecture: MW3 (26-100) Recitation: F10 (36-112, 36-153) or F11 (36-112, 36-153) or F12 (36-153) or F1 (36-153) or F2 (36-153) or F3 (36-153) or F12 (36-112) or F1 (36-112) or F2 (36-112) or F3 (36-112) or F1 (36-156) +final
______
Provides an introduction to using computation to understand real-world phenomena. Topics include plotting, stochastic programs, probability and statistics, random walks, Monte Carlo simulations, modeling data, optimization problems, and clustering. Combination of 6.0001 and 6.0002 counts as REST subject. Final given during final exam week.
J. V. Guttag
Textbooks (Fall 2016)

6.002 Circuits and Electronics
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Physics II (GIR);Coreq: 18.03 or 2.087
Units: 4-1-7
Lecture: TR11 (34-101) Lab: TBA Recitation: WF11 (26-310) or WF12 (26-310) or WF1 (26-310) or WF2 (26-310) +final
______
Fundamentals of the lumped circuit abstraction. Resistive elements and networks, independent and dependent sources, switches and MOS devices, digital abstraction, amplifiers, and energy storage elements. Dynamics of first- and second-order networks; design in the time and frequency domains; analog and digital circuits and applications. Design exercises. Occasional laboratory.
A. Agarwal, J. del Alamo, J. H. Lang, D. J. Perreault
Textbooks (Fall 2016)

6.003 Signals and Systems
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Physics II (GIR); 2.087 or 18.03
Units: 5-0-7
Lecture: TR12 (34-101) Lab: TBA Recitation: WF10 (26-210) or WF11 (26-210) or WF1 (36-144) or WF2 (36-144) +final
______
Presents the fundamentals of signal and system analysis. Topics include discrete-time and continuous-time signals, Fourier series and transforms, Laplace and Z transforms, and analysis of linear, time-invariant systems. Applications drawn broadly from engineering and physics, including audio and image processing, communications, and automatic control.
D. M. Freeman, Q. Hu, J. S. Lim
No textbook information available

6.004 Computation Structures
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Physics II (GIR)
Units: 4-0-8
URL: http://6004.mit.edu/
Lecture: TR1 (10-250) Recitation: WF10 (34-301, 13-4101) or WF11 (34-301, 13-4101) or WF12 (34-303, 36-155) or WF1 (34-303, 36-155) or WF2 (34-303, 13-5101) or WF3 (34-303, 13-5101)
______
Introduces architecture of digital systems, emphasizing structural principles common to a wide range of technologies. Multilevel implementation strategies; definition of new primitives (e.g., gates, instructions, procedures, and processes) and their mechanization using lower-level elements. Analysis of potential concurrency; precedence constraints and performance measures; pipelined and multidimensional systems. Instruction set design issues; architectural support for contemporary software structures.
S. A. Ward, C. J. Terman
No required or recommended textbooks

6.005 Elements of Software Construction
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: 6.01;Coreq: 6.042
Units: 4-0-8
Lecture: MW1-2.30,F1 (32-123)
______
Introduces fundamental principles and techniques of software development, i.e., how to write software that is safe from bugs, easy to understand, and ready for change. Topics include specifications and invariants; testing, test-case generation, and coverage; abstract data types and representation independence; design patterns for object-oriented programming; concurrent programming, including message passing and shared concurrency, and defending against races and deadlock; and functional programming with immutable data and higher-order functions. Includes weekly programming exercises and larger group programming projects. 12 Engineering Design Points.
D. N. Jackson, R. C. Miller
No required or recommended textbooks

6.006 Introduction to Algorithms
______

Undergrad (Fall, Spring)
Prereq: 6.042; 6.01 orCoreq: 6.009
Units: 4-0-8
Lecture: TR11 (26-100) Recitation: WF10 (34-304, 34-302, 35-310) or WF11 (34-304, 34-302, 36-155) or WF12 (34-301, 34-304) or WF1 (34-304, 5-134) or WF2 (5-134, 35-310) or WF3 (35-310) or WF4 (35-310) +final
______
Introduction to mathematical modeling of computational problems, as well as common algorithms, algorithmic paradigms, and data structures used to solve these problems. Emphasizes the relationship between algorithms and programming, and introduces basic performance measures and analysis techniques for these problems.
R. L. Rivest, S. Devadas
Textbooks (Fall 2016)

6.007 Electromagnetic Energy: From Motors to Solar Cells
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Physics II (GIR);Coreq: 2.087 or 18.03
Units: 5-1-6
Lecture: MWF1 (37-212) Lab: T EVE (7-9 PM) (38-601) or W EVE (7-9 PM) (38-601) +final
______
Discusses applications of electromagnetic and equivalent quantum mechanical principles to classical and modern devices. Covers energy conversion and power flow in both macroscopic and quantum-scale electrical and electromechanical systems, including electric motors and generators, electric circuit elements, quantum tunneling structures and instruments. Studies photons as waves and particles and their interaction with matter in optoelectronic devices, including solar cells and displays.
V. Bulovic, R. J. Ram
Textbooks (Fall 2016)

6.008 Introduction to Inference
______

Undergrad (Fall) Institute Lab
Prereq: Calculus II (GIR) or permission of instructor
Units: 4-4-4
F10-12 meets in 32-044. Lecture: MW10 (32-155) Lab: R3-5,F10-12 (35-225) Recitation: TR10 (3-442) or TR1 (34-302) or TR2 (34-302) +final
______
Introduces probabilistic modeling for problems of inference and machine learning from data, emphasizing analytical and computational aspects. Distributions, marginalization, conditioning, and structure; graphical representations. Belief propagation, decision-making, classification, estimation, and prediction. Sampling methods and analysis. Introduces asymptotic analysis and information measures. Substantial computational laboratory component explores the concepts introduced in class in the context of realistic contemporary applications. Students design inference algorithms, investigate their behavior on real data, and discuss experimental results.
P. Golland, G. W. Wornell
Textbooks (Fall 2016)

6.009 Fundamentals of Programming
(6.S04)
______

Undergrad (Fall, Spring) Institute Lab
Prereq: 6.0001
Units: 2-4-6
Lecture: T11-12.30 (54-100) Lab: F10-12 (35-225) or F1-3 (6-120) or F9-11 (3-333) or F1-3 (35-225) Recitation: W10-12 (32-124) or W1-3 (4-270) or W9-11 (35-225) or W1-3 (26-100)
______
Introduces fundamental concepts of programming. Designed to develop skills in applying basic methods from programming languages to abstract problems. Topics include programming and Python basics, computational concepts, software engineering, algorithmic techniques, data types, and recursion and tail recursion. Lab component consists of software design, construction, and implementation of design.
A. Chlipala, S. Devadas
No required or recommended textbooks

6.01 Introduction to EECS via Robot Sensing, Software and Control
______

Undergrad (Fall, Spring) Institute Lab
Prereq: 6.0001 or permission of instructor
Units: 2-4-6
URL: http://mit.edu/6.01/index.html
Lecture: T9.30-11 (4-270) Lab: T11-12.30,R2-5 (34-501) or T2-3.30,R9.30-12.30 (34-501) +final
______
An integrated introduction to electrical engineering and computer science, taught using substantial laboratory experiments with mobile robots. Key issues in the design of engineered artifacts operating in the natural world: measuring and modeling system behaviors; assessing errors in sensors and effectors; specifying tasks; designing solutions based on analytical and computational models; planning, executing, and evaluating experimental tests of performance; refining models and designs. Issues addressed in the context of computer programs, control systems, probabilistic inference problems, circuits and transducers, which all play important roles in achieving robust operation of a large variety of engineered systems.
D. M. Freeman, A. Hartz, L. P. Kaelbling, T. Lozano-Perez
No required or recommended textbooks

6.011 Signals, Systems and Inference
______

Undergrad (Spring)
Prereq: 6.003; 6.008, 6.041A, or 18.600
Units: 4-0-8
______
Covers signals, systems and inference in communication, control and signal processing. Topics include input-output and state-space models of linear systems driven by deterministic and random signals; time- and transform-domain representations in discrete and continuous time; and group delay. State feedback and observers. Probabilistic models; stochastic processes, correlation functions, power spectra, spectral factorization. Least-mean square error estimation; Wiener filtering. Hypothesis testing; detection; matched filters.
A. V. Oppenheim, G. C. Verghese

6.012 Microelectronic Devices and Circuits
______

Undergrad (Fall, Spring)
Prereq: 6.002
Units: 4-0-8
Lecture: TR11 (32-141) Recitation: WF1 (34-302) or WF2 (34-302) +final
______
Microelectronic device modeling, and basic microelectronic circuit analysis and design. Physical electronics of semiconductor junction and MOS devices. Relating terminal behavior to internal physical processes, developing circuit models, and understanding the uses and limitations of different models. Use of incremental and large-signal techniques to analyze and design transistor circuits, with examples chosen from digital circuits, linear amplifiers, and other integrated circuits. Design project.
A. I. Akinwande, D. A. Antoniadis, J. Kong, C. G. Sodini
Textbooks (Fall 2016)

6.013 Electromagnetics and Applications
______

Undergrad (Spring)
Prereq: Calculus II (GIR), Physics II (GIR)
Units: 3-3-6
______
Analysis and design of modern applications that employ electromagnetic phenomena for signals and power transmission in RF, microwaves, optical and wireless communication systems. Fundamentals include dynamic solutions for Maxwell's equations; electromagnetic power and energy, waves in media, guided waves, radiation, and diffraction; coupling to media and structures; resonance & filters; acoustic analogs. Labs include student hands-on activities from building to testing of devices and systems (e.g. radar) that reinforce lectures, with a focus on fostering creativity and debugging skills. 6.002 and 6.007 are recommended but not required.
L. Daniel, M. R. Watts

6.02 Introduction to EECS via Communications Networks
______

Undergrad (Fall) Institute Lab
Prereq: 6.0001
Units: 4-4-4
Lecture: MW2 (34-101) Recitation: TR10 (34-304) or TR11 (34-304) or TR12 (34-304) or TR1 (34-304) or TR2 (34-301) or TR3 (34-301) or TR10 (24-112) or TR11 (26-210) +final
______
Studies key concepts, systems, and algorithms to reliably communicate data in settings ranging from the cellular phone network and the Internet to deep space. Weekly laboratory experiments explore these areas in depth. Topics presented in three modules - bits, signals, and packets - spanning the multiple layers of a communication system. Bits module includes information, entropy, data compression algorithms, and error correction with block and convolutional codes. Signals module includes modeling physical channels and noise, signal design, filtering and detection, modulation, and frequency-division multiplexing. Packets module includes switching and queuing principles, media access control, routing protocols, and data transport protocols.
H. Balakrishnan, K. LaCurts, G. C. Verghese,
No required or recommended textbooks

6.021[J] Cellular Neurophysiology
______

Undergrad (Fall)
(Same subject as2.791[J],20.370[J])
(Subject meets with2.794[J],6.521[J],20.470[J],HST.541[J])
Prereq: Physics II (GIR); 18.03; 2.005, 6.002, 6.003, 6.071, 10.301, 20.110, or permission of instructor
Units: 5-2-5
Lecture: MWF10 (32-144) Lab: TBA Recitation: T12 (34-303) or T4 (34-302) +final
______
Integrated overview of the biophysics of cells from prokaryotes to neurons, with a focus on mass transport and electrical signal generation across cell membrane. First half of course focuses on mass transport through membranes: diffusion, osmosis, chemically mediated, and active transport. Second half focuses on electrical properties of cells: ion transport to action potentials in electrically excitable cells. Synaptic transmission. Electrical properties interpreted via kinetic and molecular properties of single voltage-gated ion channels. Laboratory and computer exercises illustrate the concepts. Students taking graduate version complete different assignments. Preference to juniors and seniors.
J. Han, T. Heldt, J. Voldman
Textbooks (Fall 2016)

6.022[J] Quantitative Systems Physiology
______

Undergrad (Spring)
(Same subject as2.792[J],HST.542[J])
(Subject meets with2.796[J],6.522[J])
Prereq: Physics II (GIR), 18.03, or permission of instructor
Units: 4-2-6
URL: http://web.mit.edu/6.022j/www/
______
Application of the principles of energy and mass flow to major human organ systems. Mechanisms of regulation and homeostasis. Anatomical, physiological and pathophysiological features of the cardiovascular, respiratory and renal systems. Systems, features and devices that are most illuminated by the methods of physical sciences. Laboratory work includes some animal studies. Students taking graduate version complete additional assignments. 2 Engineering Design Points.
T. Heldt, R. G. Mark, C. M. Stultz

6.023[J] Fields, Forces and Flows in Biological Systems
______

Undergrad (Spring)
(Same subject as2.793[J],20.330[J])
Prereq: Physics II (GIR); 2.005, 6.021, or permission of instructor,Coreq: 20.309
Units: 4-0-8
______
Introduction to electric fields, fluid flows, transport phenomena and their application to biological systems. Flux and continuity laws, Maxwell's equations, electro-quasistatics, electro-chemical-mechanical driving forces, conservation of mass and momentum, Navier-Stokes flows, and electrokinetics. Applications include biomolecular transport in tissues, electrophoresis, and microfluidics.
J. Han, S. Manalis

6.024[J] Molecular, Cellular, and Tissue Biomechanics
______

Undergrad (Spring)
(Same subject as2.797[J],3.053[J],20.310[J])
Prereq: 2.370 or 2.772J; 18.03 or 3.016; Biology (GIR)
Units: 4-0-8
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, A. J. Grodzinsky, K. Van Vliet

6.025[J] Medical Device Design
______

Undergrad (Fall)
(Same subject as2.750[J])
(Subject meets with2.75[J],6.525[J],HST.552[J])
Prereq: 2.72, 6.101, 6.111, 6.115, 22.071, or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/2.75/
Lecture: MW1-2.30 (3-270)
______
Application of mechanical and electrical engineering fundamentals to the design of medical devices that address clinical needs. Throughout the term, students work in small teams on a major project to translate a clinical challenge into a proof-of-concept prototype device. Students conduct user analysis, develop design specifications, and follow a structured process to cultivate creative designs and apply analytical techniques to optimize them. They deepen their understanding of art and intellectual property by researching prior representations. Develops practical skills in prototyping and testing as well as project management. Includes lectures, problem sets and exams that focus on design fundamentals. Instruction and practice in written and oral communication provided. Students taking graduate version complete additional assignments. Enrollment limited.
A. H. Slocum, G. Hom
No required or recommended textbooks

6.027[J] Biomolecular Feedback Systems
______

Undergrad (Spring)
(Same subject as2.180[J])
(Subject meets with2.18[J],6.557[J])
Prereq: 18.03, Biology (GIR), or permission of instructor
Units: 3-0-9
______
Comprehensive introduction to dynamics and control of biomolecular systems with emphasis on design/analysis techniques from control theory. Provides a review of biology concepts, regulation mechanisms, and models. Covers basic enabling technologies, engineering principles for designing biological functions, modular design techniques, and design limitations. Students taking graduate version complete additional assignments.
D. Del Vecchio

6.03 Introduction to EECS via Medical Technology
______

Undergrad (Spring) Institute Lab
Prereq: Calculus II (GIR), Physics II (GIR)
Units: 4-4-4
______
Explores biomedical signals generated from electrocardiograms, glucose detectors or ultrasound images, and magnetic resonance images. Topics include physical characterization and modeling of systems in the time and frequency domains; analog and digital signals and noise; basic machine learning including decision trees, clustering, and classification; and introductory machine vision. Labs designed to strengthen background in signal processing and machine learning. Students design and run structured experiments, and develop and test procedures through further experimentation.
C. M. Stultz, E. Adalsteinsson

6.031 Elements of Software Construction
(New)
______

Undergrad (Spring)
Prereq: 6.009
Units: 5-0-10
______
Introduces fundamental principles and techniques of software development: how to write software that is safe from bugs, easy to understand, and ready for change. Topics include specifications and invariants; testing, test-case generation, and coverage; abstract data types and representation independence; design patterns for object-oriented programming; concurrent programming, including message passing and shared concurrency, and defending against races and deadlock; and functional programming with immutable data and higher-order functions. Includes weekly programming exercises and larger group programming projects.
M. Goldman, R. C. Miller

6.033 Computer System Engineering
______

Undergrad (Spring)
Prereq: 6.004; 6.005 or 6.009
Units: 5-1-6
URL: http://web.mit.edu/6.033/www/
______
Topics on the engineering of computer software and hardware systems: techniques for controlling complexity; strong modularity using client-server design, operating systems; performance, networks; naming; security and privacy; fault-tolerant systems, atomicity and coordination of concurrent activities, and recovery; impact of computer systems on society. Case studies of working systems and readings from the current literature provide comparisons and contrasts. Includes a single, semester-long design project. Students engage in extensive written communication exercises. Enrollment may be limited.
K. LaCurts, M. F. Kaashoek, H. Balakrishnan

6.034 Artificial Intelligence
______

Undergrad (Fall)
Prereq: 6.0001
Units: 4-3-5
URL: http://courses.csail.mit.edu/6.034/
Lecture: MWF10 (10-250) Recitation: M11 (26-302, 34-301, 34-302, 34-304) or M12 (34-302) or M11 (36-372) or M12 (34-304) or M1 (34-303, 34-304) or M2 (34-301, 34-304) or M3 (34-304) or M11 (38-166) or T10 (34-301, 34-302) or T11 (34-301) or T12 (26-328, 34-301) or T1 (34-301, 34-303) or T2 (34-303) or T3 (34-303) or M12 (38-166, 26-302) or T11 (26-302) +final
______
Introduces representations, methods, and architectures used to build applications and to account for human intelligence from a computational point of view. Covers applications of rule chaining, constraint propagation, constrained search, inheritance, statistical inference, and other problem-solving paradigms. Also addresses applications of identification trees, neural nets, genetic algorithms, support-vector machines, boosting, and other learning paradigms. Considers what separates human intelligence from that of other animals.
P. H. Winston
No textbook information available

6.035 Computer Language Engineering
______

Undergrad (Fall)
Prereq: 6.004; 6.005 or 6.031
Units: 4-4-4
URL: http://web.mit.edu/6.035/6035.html
Lecture: MWF11 (3-370) Recitation: TR11 (4-149)
______
Analyzes issues associated with the implementation of higher-level programming languages. Fundamental concepts, functions, and structures of compilers. The interaction of theory and practice. Using tools in building software. Includes a multi-person project on compiler design and implementation.
M. C. Rinard
No textbook information available

6.036 Introduction to Machine Learning
______

Undergrad (Spring)
(Subject meets with6.862)
Prereq: 6.0001
Units: 4-0-8
______
Introduces principles, algorithms, and applications of machine learning from the point of view of modeling and prediction; formulation of learning problems; representation, over-fitting, generalization; clustering, classification, probabilistic modeling; and methods such as support vector machines, hidden Markov models, and Bayesian networks. Students taking graduate version complete additional assignments.
R. Barzilay, T. Jaakkola, L. P. Kaelbling

6.037 Structure and Interpretation of Computer Programs
______

Undergrad (IAP)
Prereq: None
Units: 1-0-5 [P/D/F]
______
Studies the structure and interpretation of computer programs which transcend specific programming languages. Demonstrates thought patterns for computer science using Scheme. Includes weekly programming projects. Enrollment may be limited.
Staff

6.041A Introduction to Probability I
(New)
______

Undergrad (Fall, Spring); first half of term
(Subject meets with6.431A)
Prereq: Calculus II (GIR)
Units: 2-0-4
Ends Oct 21. Lecture: MW12 (34-101) Recitation: TR11 (24-121) or TR12 (24-121) or TR1 (24-121) or TR2 (24-121)
______
Provides an introduction to probability theory and the modeling and analysis of probabilistic systems. Probabilistic models, conditional probability. Discrete and continuous random variables. Expectation and conditional expectation. Limit Theorems. Students taking graduate version complete additional assignments. Combination of 6.041A and 6.041B counts as a REST subject.
P. Jaillet, J. N. Tsitsiklis
No textbook information available

6.041B Introduction to Probability II
(New)
______

Undergrad (Fall, Spring); second half of term
(Subject meets with6.431B)
Prereq: 6.041A
Units: 2-0-4
Begins Oct 24. Lecture: MW12 (34-101) Recitation: TR11 (24-121) or TR12 (24-121) or TR1 (24-121) or TR2 (24-121) +final
______
Building on 6.041A, further discusses topics in probability. Bayesian estimation and hypothesis testing. Elements of statistical inference. Bernoulli and Poisson processes. Markov chains. Students taking graduate version complete additional assignments. Combination of 6.041A and 6.041B counts as a REST subject.
P. Jaillet, J. N. Tsitsiklis
No textbook information available

6.042[J] Mathematics for Computer Science
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
(Same subject as18.062[J])
Prereq: Calculus I (GIR)
Units: 5-0-7
URL: http://theory.csail.mit.edu/classes/6.042
Lecture: TR2.30-4 (26-100) Recitation: WF9 (38-166) or WF10 (38-166) or WF11 (38-166) or WF12 (38-166) or WF1 (38-166) or WF2 (38-166) or WF3 (38-166) or WF4 (38-166) or WF10 (13-3101) or WF11 (13-3101) or WF12 (13-3101) or WF1 (13-3101) or WF2 (13-3101) or WF3 (13-3101) or WF4 (13-3101) or WF10 (26-168) or WF11 (26-168) or WF12 (26-168) or WF1 (26-168) or WF2 (26-168) or WF3 (26-168) or WF4 (26-168) or WF11 (24-112) or WF12 (24-112) or WF1 (24-112) or WF9 (26-168) +final
______
Elementary discrete mathematics for computer science and engineering. Emphasis on mathematical definitions and proofs as well as on applicable methods. Topics include formal logic notation, proof methods; induction, well-ordering; sets, relations; elementary graph theory; asymptotic notation and growth of functions; permutations and combinations, counting principles; discrete probability. Further selected topics include recursive definition and structural induction, state machines and invariants, integer congruences, recurrences, generating functions.
F. T. Leighton, A. R. Meyer, A. Moitra
No required or recommended textbooks

6.045[J] Automata, Computability, and Complexity
______

Undergrad (Spring)
(Same subject as18.400[J])
Prereq: 6.042
Units: 4-0-8
URL: http://math.mit.edu/classes/18.400
______
Provides an introduction to some of the central ideas of theoretical computer science, including circuits, finite automata, Turing machines and computability, efficient algorithms and reducibility, the P versus NP problem, NP-completeness, the power of randomness, cryptography, computational learning theory, and quantum computing. Examines the classes of problems that can and cannot be solved in various computational models.
S. Aaronson

6.046[J] Design and Analysis of Algorithms
______

Undergrad (Fall, Spring)
(Same subject as18.410[J])
Prereq: 6.006
Units: 4-0-8
URL: http://math.mit.edu/classes/18.410
Lecture: TR11-12.30 (32-123) Recitation: F10 (4-159) or F11 (4-159, 4-149, 36-156) or F12 (36-156, 4-159) or F1 (4-159, 4-149) or F2 (35-308) or F3 (35-308) +final
______
Techniques for the design and analysis of efficient algorithms, emphasizing methods useful in practice. Topics include sorting; search trees, heaps, and hashing; divide-and-conquer; dynamic programming; greedy algorithms; amortized analysis; graph algorithms; and shortest paths. Advanced topics may include network flow; computational geometry; number-theoretic algorithms; polynomial and matrix calculations; caching; and parallel computing.
E. Demaine, M. Goemans
Textbooks (Fall 2016)

6.047 Computational Biology: Genomes, Networks, Evolution
______

Undergrad (Fall)
(Subject meets with6.878[J],HST.507[J])
Prereq: 6.006, 6.041B, Biology (GIR); or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (32-141) Recitation: F3 (4-237)
______
Covers the algorithmic and machine learning foundations of computational biology, combining theory with practice. Principles of algorithm design, influential problems and techniques, and analysis of large-scale biological datasets. Topics include (a) genomes: sequence analysis, gene finding, RNA folding, genome alignment and assembly, database search; (b) networks: gene expression analysis, regulatory motifs, biological network analysis; (c) evolution: comparative genomics, phylogenetics, genome duplication, genome rearrangements, evolutionary theory. These are coupled with fundamental algorithmic techniques including: dynamic programming, hashing, Gibbs sampling, expectation maximization, hidden Markov models, stochastic context-free grammars, graph clustering, dimensionality reduction, Bayesian networks.
M. Kellis
No textbook information available

6.049[J] Evolutionary Biology: Concepts, Models and Computation
______

Undergrad (Spring)
(Same subject as7.33[J])
Prereq: 7.03; 6.0001 or permission of instructor
Units: 3-0-9
______
Explores and illustrates how evolution explains biology, with an emphasis on computational model building for analyzing evolutionary data. Covers key concepts of biological evolution, including adaptive evolution, neutral evolution, evolution of sex, genomic conflict, speciation, phylogeny and comparative methods, life's history, coevolution, human evolution, and evolution of disease.
R. Berwick, D. Bartel

6.050[J] Information, Entropy, and Computation
______

Undergrad (Spring)
(Same subject as2.110[J])
Prereq: Physics I (GIR)
Units: 3-0-6
______
Explores the ultimate limits to communication and computation, with an emphasis on the physical nature of information and information processing. Topics include information and computation, digital signals, codes, and compression. Biological representations of information. Logic circuits, computer architectures, and algorithmic information. Noise, probability, and error correction. The concept of entropy applied to channel capacity and to the second law of thermodynamics. Reversible and irreversible operations and the physics of computation. Quantum computation.
P. Penfield, Jr., S. Lloyd

6.057 Introduction to MATLAB
______

Undergrad (IAP)
Prereq: None
Units: 1-0-2 [P/D/F]
______
Accelerated introduction to MATLAB and its popular toolboxes. Lectures are interactive, with students conducting sample MATLAB problems in real time. Includes problem-based MATLAB assignments. Students must provide their own laptop and software. Enrollment limited.
Staff

6.058 Introduction to Signals and Systems, and Feedback Control
______

Undergrad (IAP)
Prereq: Calculus II (GIR) or permission of instructor
Units: 2-2-2 [P/D/F]
______
Introduces fundamental concepts for 6.003, including Fourier and Laplace transforms, convolution, sampling, filters, feedback control, stability, and Bode plots. Students engage in problem solving, using Mathematica and MATLAB software extensively to help visualize processing in the time frequency domains.
Staff

6.061 Introduction to Electric Power Systems
______

Not offered academic year 2017-2018Undergrad (Spring)
(Subject meets with6.690)
Prereq: 6.002, 6.013
Units: 3-0-9
______
Electric circuit theory with application to power handling electric circuits. Modeling and behavior of electromechanical devices, including magnetic circuits, motors, and generators. Operational fundamentals of synchronous, induction and DC machinery. Interconnection of generators and motors with electric power transmission and distribution circuits. Power generation, including alternative and sustainable sources. Students taking graduate version complete additional assignments.
J. L. Kirtley, Jr.

6.07[J] Projects in Microscale Engineering for the Life Sciences
______

Undergrad (Spring)
Not offered regularly; consult department
(Same subject asHST.410[J])
Prereq: None
Units: 2-4-3
______
A project-based introduction to manipulating and characterizing cells and biological molecules using microfabricated tools. In the first half of the term, students perform laboratory exercises designed to introduce the design, manufacture, and use of microfluidic channels; techniques for sorting and manipulating cells and biomolecules; and making quantitative measurements using optical detection and fluorescent labeling. In the second half of the term, students work in small groups to design and test a microfluidic device to solve a real-world problem of their choosing. Includes exercises in written and oral communication and team building. Limited to 20; preference to freshmen.
D. Freeman, M. Gray

6.070[J] Electronics Project Laboratory
______

Undergrad (Fall, Spring)
(Same subject asEC.120[J])
Prereq: None
Units: 2-2-2
Lecture: M EVE (7-10 PM) (4-409)
______
Intuition-based introduction to electronics, electronic components and test equipment such as oscilloscopes, meters (voltage, resistance inductance, capacitance, etc.), and signal generators. Emphasizes individual instruction and development of skills, such as soldering, assembly, and troubleshooting. Students design, build, and keep a small electronics project to put their new knowledge into practice. Intended for students with little or no previous background in electronics. Enrollment may be limited.
J. Bales
No required or recommended textbooks

6.071[J] Electronics, Signals, and Measurement
______

Undergrad (Spring) Rest Elec in Sci & Tech
(Same subject as22.071[J])
Prereq: 18.03
Units: 3-3-6
URL: http://www.mit.edu:8001/courses/6.071/
______
Provides the knowledge necessary for reading schematics and designing, building, analyzing, and testing fundamental analog and digital circuits. Students construct interactive examples and explore the practical uses of electronics in engineering and experimental science, including signals and measurement fundamentals. Uses state-of-the-art hardware and software for data acquisition, analysis, and control. Suitable for students with little or no previous background in electronics.
A. White

6.072[J] Introduction to Digital Electronics
______

Undergrad (Fall, Spring)
(Same subject asEC.110[J])
Prereq: None
Units: 0-3-3 [P/D/F]
Lecture: M EVE (7-10 PM) (4-402)
______
Design your own circuits for times when off-the-shelf solutions are not available. Seminar begins with assembly of a utility board. Weekly labs cover digital logic gates, memory elements, and finite-state machine design. Seminar concludes with a team-based design project. Preference given to freshmen. Maximum of 10 students per term, lottery at the first class session if oversubscribed .
J. Bales
No required or recommended textbooks

6.073[J] Creating Video Games
______

Undergrad (Spring) HASS Arts
(Same subject asCMS.611[J])
Prereq: 6.01, CMS.301, or CMS.608
Units: 3-3-6
______
Introduces students to the complexities of working in small, multidisciplinary teams to develop video games. Covers creative design and production methods, stressing design iteration and regular testing across all aspects of game development (design, visual arts, music, fiction, and programming). Assumes a familiarity with current video games, and the ability to discuss games critically. Previous experience in audio design, visual arts, or project management recommended. Limited to 24.
P. Tan, S. Verrilli, R. Eberhardt

6.S062 Special Subject in Electrical Engineering and Computer Science
______

Undergrad (Fall) Can be repeated for credit
Prereq: None
Units arranged
URL: http://www.eecs.mit.edu/academics-admissions/academic-information/subject-updates-st-2016
Lecture: M3-5 (36-153)
______
Basic undergraduate subjects not offered in the regular curriculum.
Consult Department
No textbook information available

6.S063, 6.S064 Special Subject in Electrical Engineering and Computer Science
______

Undergrad (Fall) Can be repeated for credit
Prereq: None
Units arranged
6.S064: URL: https://www.eecs.mit.edu/academics-admissions/academic-information/subject-updates-ft-2016/6s064
6.S063: TBA.
6.S064: Lecture: TR11 (34-101) +final
______
Basic undergraduate subjects not offered in the regular curriculum.
Consult Department
6.S063: No textbook information available
6.S064: No textbook information available

6.S08 Special Subject: Interconnected Embedded Systems
______

Undergrad (Spring) Institute Lab
Prereq: None
Units: 1-5-6
______
Introduction to embedded systems in the context of connected devices, wearables and the "Internet of Things". Topics include microcontrollers, energy utilization, algorithmic efficiency, interfacing with sensors, networking, cryptography, local versus distributed computation, data analytics, and 3D printing. Students will design, make, and program an internet-connected wearable device. Final project where student teams will design and demo their own cloud-connected wearable system. Licensed for Spring 2016 by the Committee on Curricula. Enrollment limited; preference to first- and second-year students.
J. Voldman, J. D. Steinmeyer

6.S076-6.S084 Special Subject in Electrical Engineering and Computer Science
______

Undergrad (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
6.S082: URL: http://www.eecs.mit.edu/academics-admissions/academic-information/subject-updates-ft-2016
6.S080: TBA.
Subject Cancelled 6.S082 Cancelled
6.S084: Lecture: MW1-2.30 (1-150)
______
Covers subject matter not offered in the regular curriculum. Consult department to learn of offerings for a particular term.
Consult Department
6.S080: No required or recommended textbooks
6.S084: No textbook information available

6.S085-6.S099 Special Subject in Electrical Engineering and Computer Science
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Covers subject matter not offered in the regular curriculum. Consult department to learn of offerings for a particular term.
Consult Department

Undergraduate Laboratory Subjects

6.100 Electrical Engineering and Computer Science Project
______

Undergrad (Fall, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Individual experimental work related to electrical engineering and computer science. Student must make arrangements with a project supervisor and file a proposal endorsed by the supervisor. Departmental approval required. Written report to be submitted upon completion of work.
Consult Department Undergraduate Office
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

6.101 Introductory Analog Electronics Laboratory
______

Undergrad (Spring) Institute Lab
Prereq: 6.002 or 6.071
Units: 2-9-1
URL: http://web.mit.edu/6.101/www/
______
Introductory experimental laboratory explores the design, construction, and debugging of analog electronic circuits. Lectures and laboratory projects in the first half of the course investigate the performance characteristics of semiconductor devices (diodes, BJTs, and MOSFETs) and functional analog building blocks, including single-stage amplifiers, op amps, small audio amplifier, filters, converters, sensor circuits, and medical electronics (ECG, pulse-oximetry). Projects involve design, implementation, and presentation in an environment similar to that of industry engineering design teams. Instruction and practice in written and oral communication provided. Opportunity to simulate real-world problems and solutions that involve tradeoffs and the use of engineering judgment. Engineers from local companies help students with their design projects.
G. Hom

6.111 Introductory Digital Systems Laboratory
______

Undergrad (Fall) Institute Lab
Prereq: 6.002, 6.071, or 16.004
Units: 3-7-2
Lecture: TR2.30-4 (32-124) Lab: TBA
______
Lectures and labs on digital logic, flip flops, PALs, FPGAs, counters, timing, synchronization, and finite-state machines prepare students for the design and implementation of a final project of their choice: games, music, digital filters, wireless communications, video, or graphics. Extensive use of Verilog for describing and implementing digital logic designs.
A. P. Chandrakasan, G. P. Hom
No required or recommended textbooks

6.115 Microcomputer Project Laboratory
______

Undergrad (Spring) Institute Lab
(Subject meets with6.1151)
Prereq: 6.002, 6.003, 6.004, or 6.007
Units: 3-6-3
______
Introduces analysis and design of embedded systems. Microcontrollers provide adaptation, flexibility, and real-time control. Emphasizes construction of complete systems, including a five-axis robot arm, a fluorescent lamp ballast, a tomographic imaging station (e.g., a CAT scan), and a simple calculator. Presents a wide range of basic tools, including software and development tools, programmable system on chip, peripheral components such as A/D converters, communication schemes, signal processing techniques, closed-loop digital feedback control, interface and power electronics, and modeling of electromechanical systems. Includes a sequence of assigned projects, followed by a final project of the student's choice, emphasizing creativity and uniqueness. Provides instruction in written and oral communication. Students taking independent inquiry version 6.1151 expand the scope of their laboratory project.
S. B. Leeb

6.1151 Microcomputer Project Laboratory - Independent Inquiry
(New)
______

Undergrad (Spring)
(Subject meets with6.115)
Prereq: 6.002, 6.003, 6.004, or 6.007
Units: 3-9-3
______
Introduces analysis and design of embedded systems. Microcontrollers provide adaptation, flexibility, and real-time control. Emphasizes construction of complete systems, including a five-axis robot arm, a fluorescent lamp ballast, a tomographic imaging station (e.g., a CAT scan), and a simple calculator. Presents a wide range of basic tools, including software and development tools, programmable system on chip, peripheral components such as A/D converters, communication schemes, signal processing techniques, closed-loop digital feedback control, interface and power electronics, and modeling of electromechanical systems. Includes a sequence of assigned projects, followed by a final project of the student's choice, emphasizing creativity and uniqueness. Provides instruction in written and oral communication. Students taking independent inquiry version 6.1151 expand the scope of their laboratory project.
S. B. Leeb

6.117 Introduction to Electrical Engineering Lab Skills
______

Undergrad (IAP)
Prereq: None
Units: 1-3-2 [P/D/F]
______
Introduces basic electrical engineering concepts, components, and laboratory techniques. Covers analog integrated circuits, power supplies, and digital circuits. Lab exercises provide practical experience in constructing projects using multi-meters, oscilloscopes, logic analyzers, and other tools. Includes a project in which students build a circuit to display their own EKG. Enrollment limited.
G. P. Hom

6.123[J] Bioinstrumentation Project Lab
______

Undergrad (Spring)
(Same subject as20.345[J])
Prereq: Biology (GIR), and 2.004 or 6.003; or 20.309; or permission of instructor
Units: 2-7-3
______
In-depth examination of instrumentation design, principles and techniques for studying biological systems, from single molecules to entire organisms. Lectures cover optics, advanced microscopy techniques, electronics for biological measurement, magnetic resonance imaging, computed tomography, MEMs, microfluidic devices, and limits of detection. Students select two lab exercises during the first half of the semester and complete a final design project in the second half. Lab emphasizes design process and skillful realization of a robust system. Enrollment limited; preference to Course 20 majors and minors.
E. Boyden, M. Jonas, S. F. Nagle, P. So, S. Wasserman, M. F. Yanik

6.129[J] Biological Circuit Engineering Laboratory
______

Undergrad (Spring) Institute Lab
(Same subject as20.129[J])
Prereq: Biology (GIR), Calculus II (GIR)
Units: 2-8-2
______
Students assemble individual genes and regulatory elements into larger-scale circuits; they experimentally characterize these circuits in yeast cells using quantitative techniques, including flow cytometry, and model their results computationally. Emphasizes concepts and techniques to perform independent experimental and computational synthetic biology research. Discusses current literature and ongoing research in the field of synthetic biology. Instruction and practice in oral and written communication provided. Enrollment limited.
T. Lu, R. Weiss

6.131 Power Electronics Laboratory
______

Undergrad (Fall) Institute Lab
(Subject meets with6.1311)
Prereq: 6.002, 6.003, or 6.007
Units: 3-6-3
Lecture: TR1 (34-101) Lab: W3 (34-101)
______
Introduces the design and construction of power electronic circuits and motor drives. Laboratory exercises include the construction of drive circuitry for an electric go-cart, flash strobes, computer power supplies, three-phase inverters for AC motors, and resonant drives for lamp ballasts and induction heating. Basic electric machines introduced include DC, induction, and permanent magnet motors, with drive considerations. Provides instruction in written and oral communication. Students taking independent inquiry version 6.1131 expand the scope of their laboratory project.
S. B. Leeb
Textbooks (Fall 2016)

6.1311 Power Electronics Laboratory - Independent Inquiry
(New)
______

Undergrad (Fall)
(Subject meets with6.131)
Prereq: 6.002, 6.003, or 6.007
Units: 3-9-3
Lecture: TR1 (34-101) Lab: W3 (34-101)
______
Introduces the design and construction of power electronic circuits and motor drives. Laboratory exercises include the construction of drive circuitry for an electric go-cart, flash strobes, computer power supplies, three-phase inverters for AC motors, and resonant drives for lamp ballasts and induction heating. Basic electric machines introduced include DC, induction, and permanent magnet motors, with drive considerations. Provides instruction in written and oral communication. Students taking independent inquiry version 6.1131 expand the scope of their laboratory project.
S. B. Leeb
Textbooks (Fall 2016)

6.141[J] Robotics: Science and Systems
______

Undergrad (Spring) Institute Lab
(Same subject as16.405[J])
Prereq: 1.00 or 6.0001; 2.003, 6.005, 6.006, 6.009, or 16.06; or permission of instructor
Units: 2-6-4
URL: http://courses.csail.mit.edu/rss/
______
Presents concepts, principles, and algorithms for sensing and computation related to the physical world. Topics include motion planning, geometric reasoning, kinematics and dynamics, state estimation, tracking, map building, manipulation, human-robot interaction, fault diagnosis, and embedded system development. Students specify and design a small-scale yet complex robot capable of real-time interaction with the natural world. Students engage in extensive written and oral communication exercises. Enrollment limited.
S. Karaman, D. Rus

6.146 Mobile Autonomous Systems Laboratory: MASLAB
______

Undergrad (IAP) Can be repeated for credit
Prereq: None
Units: 2-2-2 [P/D/F]
______
Autonomous robotics contest emphasizing technical AI, vision, mapping and navigation from a robot-mounted camera. Few restrictions are placed on materials, sensors, and/or actuators enabling teams to build robots very creatively. Teams should have members with varying engineering, programming and mechanical backgrounds. Culminates with a robot competition at the end of IAP. Enrollment limited.
Staff

6.147 The Battlecode Programming Competition
______

Undergrad (IAP) Can be repeated for credit
Prereq: None
Units: 2-0-4 [P/D/F]
URL: http://www.battlecode.org
______
Artificial Intelligence programming contest in Java. Student teams program virtual robots to play Battlecode, a real-time strategy game. Competition culminates in a live BattleCode tournament. Assumes basic knowledge of programming.
Staff

6.148 Web Programming Competition
______

Undergrad (IAP) Can be repeated for credit
Prereq: Permission of instructor
Units: 1-0-5 [P/D/F]
______
Teams compete to build the most functional and user-friendly website. Competition is judged by industry experts and includes novice and advanced divisions. Prizes awarded. Lectures and workshops cover website basics. Enrollment limited.
Staff

6.149 Introduction to Programming Using Python
______

Not offered academic year 2016-2017Undergrad (IAP)
Prereq: None
Units: 3-0-3 [P/D/F]
______
Fact-paced introduction to Python programming language for students with little or no programming experience. Covers both function and object-oriented concepts. Includes weekly lab exercises and final project. Enrollment limited.
Staff

6.150 Mobile Applications Competition
______

Undergrad (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 2-2-2 [P/D/F]
______
Student teams design and build an Android application based on a given theme. Lectures and labs led by experienced students and leading industry experts, covering the basics of Android development, concepts and tools to help participants build great apps. Contest culminates with a public presentation in front of a judging panel comprised of professional developers and MIT faculty. Prizes awarded. Enrollment limited.
Staff

6.151 iOS Game Design and Development Competition
______

Undergrad (IAP)
Prereq: None
Units: 2-2-2 [P/D/F]
______
Introduction to iOS game design and development for students already familiar with object-oriented programming. Provides a set of basic tools (Objective-C and Cocos2D) and exposure to real-world issues in game design. Working in small teams, students complete a final project in which they create their own iPhone game. At the end of IAP, teams present their games in competition for prizes awarded by a judging panel of gaming experts.
Staff

6.152[J] Micro/Nano Processing Technology
______

Undergrad (Fall)
(Same subject as3.155[J])
Prereq: Permission of instructor
Units: 3-4-5
Lecture: MW2.30-4 (32-124)
______
Introduces the theory and technology of micro/nano fabrication. Lectures and laboratory sessions on basic processing techniques such as vacuum processes, lithography, diffusion, oxidation, and pattern transfer. Students fabricate MOS capacitors, nanomechanical cantilevers, and microfluidic mixers. Emphasis on the interrelationships between material properties and processing, device structure, and the electrical, mechanical, optical, chemical or biological behavior of devices. Provides background for thesis work in micro/nano fabrication. Students engage in extensive written and oral communication exercises.
L. F. Velasquez-Garcia, J. Michel
Textbooks (Fall 2016)

6.161 Modern Optics Project Laboratory
______

Undergrad (Fall) Institute Lab
(Subject meets with6.637)
Prereq: 6.003
Units: 3-5-4
URL: http://web.mit.edu/6.161/www/index.html
Lecture: TR2.30-4 (34-304) Lab: TBA
______
Lectures, laboratory exercises and projects on optical signal generation, transmission, detection, storage, processing and display. Topics include polarization properties of light; reflection and refraction; coherence and interference; Fraunhofer and Fresnel diffraction; holography; Fourier optics; coherent and incoherent imaging and signal processing systems; optical properties of materials; lasers and LEDs; electro-optic and acousto-optic light modulators; photorefractive and liquid-crystal light modulation; display technologies; optical waveguides and fiber-optic communication systems; photodetectors. Students may use this subject to find an advanced undergraduate project. Students engage in extensive oral and written communcation exercises. Recommended prerequisites: 6.007 or 8.03.
C. Warde
No textbook information available

6.163 Strobe Project Laboratory
______

Undergrad (Fall, Spring) Institute Lab
Prereq: Physics II (GIR) or permission of instructor
Units: 2-8-2
Lecture: MW12 (4-149) Lab: TBA
______
Application of electronic flash sources to measurement and photography. First half covers fundamentals of photography and electronic flashes, including experiments on application of electronic flash to photography, stroboscopy, motion analysis, and high-speed videography. Students write four extensive lab reports. In the second half, students work in small groups to select, design, and execute independent projects in measurement or photography that apply learned techniques. Project planning and execution skills are discussed and developed over the term. Students engage in extensive written and oral communication exercises. Enrollment limited.
J. K. Vandiver, J. W. Bales
No required or recommended textbooks

6.169 Theory and Application of Circuits and Electronics
______

Undergrad (Fall, Spring)
Prereq: None.Coreq: 6.002
Units: 1-1-1
Lecture: F3 (4-231) Recitation: TBA
______
Building on the framework of 6.002, provides a deeper understanding of the theory and applications of circuits and electronics.
A. Agarwal, J. del Alamo, J. H. Lang, D. J. Perreault
No textbook information available

6.170 Software Studio
______

Undergrad (Fall)
Prereq: 6.006; 6.005 or 6.031
Units: 4-0-8
URL: http://www.mit.edu/~6.170/
Lecture: MW2.30-4 (32-123) Recitation: R1 (38-166) or R2 (38-166) or R3 (38-166) or R11 (66-144) or R12 (66-144) or R1 (66-144) or R2 (66-144) or R3 (66-144) or R10 (38-166) or R11 (38-166) or R12 (38-166) or R4 (38-166)
______
Covers design and implementation of software systems, using web applications as the platform. Emphasizes the role of conceptual design in achieving clarity, simplicity, and modularity. Students complete open-ended individual assignments and a major team project. Enrollment may be limited.
D. N. Jackson
No textbook information available

6.172 Performance Engineering of Software Systems
______

Undergrad (Fall)
(Subject meets with6.871)
Prereq: 6.004, 6.006; 6.005 or 6.031
Units: 3-12-3
Lecture: TR2.30-4 (34-101) Lab: F10-12 (4-265) or F1-3 (4-265) or F3-5 (4-265) or F10-12 (24-307) or F1-3 (34-301) or F3-5 (34-301) or F2-4 (34-304) or F3-5 (36-155)
______
Project-based introduction to building efficient, high-performance and scalable software systems. Topics include performance analysis, algorithmic techniques for high performance, instruction-level optimizations, vectorization, cache and memory hierarchy optimization, and parallel programming. Students taking graduate version complete additional assignments.
S. Amarasinghe, C. E. Leiserson
No textbook information available

6.175 Constructive Computer Architecture
______

Undergrad (Fall)
Prereq: 6.004
Units: 3-8-1
Lecture: MWF3 (34-302)
______
Illustrates a constructive (as opposed to a descriptive) approach to computer architecture. Topics include combinational and pipelined arithmetic-logic units (ALU), in-order pipelined microarchitectures, branch prediction, blocking and unblocking caches, interrupts, virtual memory support, cache coherence and multicore architectures. Labs in a modern Hardware Design Language (HDL) illustrate various aspects of microprocessor design, culminating in a term project in which students present a multicore design running on an FPGA board.
Arvind
No textbook information available

6.176 Pokerbots Competition
______

Undergrad (IAP) Can be repeated for credit
Prereq: None
Units: 1-0-5 [P/D/F]
______
Build autonomous poker players and aquire the knowledge of the game of poker. Showcase decision making skills, apply concepts in mathematics, computer science and economics. Provides instruction in programming, game theory, probability and statistics and machine learning. Concludes with a final competition and prizes. Enrollment limited
Staff

6.177 Building Programming Experience in Python
______

Not offered academic year 2016-2017Undergrad (IAP)
Prereq: None
Units: 1-0-5 [P/D/F]
______
Preparation for 6.01 aimed to sharpen skills in program design, implementation, and debugging in Python. Programming intensive, with one short structured assignment and a supervised, but highly individual, mandatory project presentation. Intended for students with some elementary programming experience (equivalent to AP Computer Science). Enrollment limited.
Staff

6.178 Introduction to Software Engineering in Java
______

Undergrad (IAP)
Prereq: None
Units: 1-1-4 [P/D/F]
______
Covers the fundamentals of Java, helping students develop intuition about object-oriented programming. Focuses on developing working software that solves real problems. Designed for students with little or no programming experience. Concepts covered useful to 6.005. Enrollment limited.
Staff

6.179 Introduction to C and C++
______

Undergrad (IAP)
Prereq: None
Units: 3-3-0 [P/D/F]
______
Fast-paced introduction to the C and C++ programming languages. Intended for those with experience in other languages who have never used C or C++. Students complete daily assignments, a small-scale individual project, and a mandatory online diagnostic test. Enrollment limited.
Staff

6.182 Psychoacoustics Project Laboratory
______

Undergrad (Spring) Institute Lab
Prereq: None
Units: 3-6-3
______
Introduces the methods used to measure human auditory abilities. Discusses auditory function, principles of psychoacoustic measurement, models for psychoacoustic performance, and experimental techniques. Project topics: absolute and differential auditory sensitivity, operating characteristics of human observers, span of auditory judgment, adaptive measurement procedures, and scaling sensory magnitudes. Knowledge of probability helpful. Students engage in extensive written and oral communication exercises.
L. D. Braida

6.S183-6.S192 Special Laboratory Subject in Electrical Engineering and Computer Science
______

Undergrad (IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Laboratory subject that covers content not offered in the regular curriculum. Consult department to learn of offerings for a particular term.
Consult Department

6.S193-6.S198 Special Laboratory Subject in Electrical Engineering and Computer Science
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
6.S194: URL: http://www.eecs.mit.edu/academics-admissions/academic-information/subject-updates-st-2016
______
Laboratory subject that covers content not offered in the regular curriculum. Consult department to learn of offerings for a particular term.
D. M. Freeman

Senior Projects

6.UAP Undergraduate Advanced Project
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 6.UAT
Units: 0-6-0
URL: http://www.eecs.mit.edu/ug/uap.html
Consult department TBA.
______
Research project for those students completing the SB degree, to be arranged by the student and an appropriate MIT faculty member. Students who register for this subject must consult the department undergraduate office. Students engage in extensive written communications exercises.
Consult Department Undergraduate Office
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

6.UAR Seminar in Undergraduate Advanced Research
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: 6.UR
Units: 2-0-4
URL: https://superurop.eecs.mit.edu/
Lecture: R4 (32-123)
______
Instruction in effective undergraduate research, including choosing and developing a research topic, surveying previous work and publications, research topics in EECS, industry best practices, design for robustness, technical presentation, authorship and collaboration, and ethics. Material covered over both fall and spring terms. Students engage in extensive written and oral communication exercises, in the context of an approved advanced research project. May be repeated for credit for a maximum of 12 units.
A. P. Chandrakasan, D. M. Freeman
No required or recommended textbooks

6.UAT Oral Communication
______

Undergrad (Fall, Spring)
Prereq: None
Units: 3-0-6
URL: https://courses.csail.mit.edu/6.UAT/main.php
Lecture: MW1 (34-101)
______
Provides instruction in aspects of effective technical oral presentations and exposure to communication skills useful in a workplace setting. Students create, give and revise a number of presentations of varying length targeting a range of different audiences.
T. L. Eng
No textbook information available

6.URS Undergraduate Research in Electrical Engineering and Computer Science
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
Consult department TBA.
______
Year-long individual research project arranged with appropriate faculty member or approved supervisor. Forms and instructions for the proposal and final report are available in the EECS Undergraduate Office.
A. P. Chandrakasan, D. M. Freeman
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

Advanced Undergraduate Subjects and Graduate Subjects by Area

Systems Science and Control Engineering

6.207[J] Networks
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Social Sciences
(Same subject as14.15[J])
Prereq: 6.041B or 14.30
Units: 4-0-8
______
Highlights common principles that permeate the functioning of diverse technological, economic and social networks. Utilizes three sets of tools for analyzing networks--random graph models, optimization, and game theory--to study informational and learning cascades; economic and financial networks; social influence networks; formation of social groups; communication networks and the Internet; consensus and gossiping; spread and control of epidemics; control and use of energy networks; and biological networks.
Consult Department Headquarters

6.231 Dynamic Programming and Stochastic Control
______

Graduate (Spring)
Prereq: 6.041B or 18.204; 18.100A, 18.100B, or 18.100Q
Units: 3-0-9
URL: http://web.mit.edu/6.231/www/6231.html
______
Sequential decision-making via dynamic programming. Unified approach to optimal control of stochastic dynamic systems and Markovian decision problems. Applications in linear-quadratic control, inventory control, resource allocation, scheduling, and planning. Optimal decision making under perfect and imperfect state information. Certainty equivalent, open loop-feedback control, rollout, model predictive control, aggregation, and other suboptimal control methods. Infinite horizon problems: discounted, stochastic shortest path, average cost, and semi-Markov models. Value and policy iteration. Abstract models in dynamic programming. Approximate/neurodynamic programming. Simulation based methods. Discussion of current research on the solution of large-scale problems.
J. N. Tsitsiklis

6.241[J] Dynamic Systems and Control
______

Graduate (Spring)
(Same subject as16.338[J])
Prereq: 6.003, 18.06
Units: 4-0-8
______
Linear, discrete- and continuous-time, multi-input-output systems in control, related areas. Least squares and matrix perturbation problems. State-space models, modes, stability, controllability, observability, transfer function matrices, poles and zeros, and minimality. Internal stability of interconnected systems, feedback compensators, state feedback, optimal regulation, observers, and observer-based compensators. Measures of control performance, robustness issues using singular values of transfer functions. Introductory ideas on nonlinear systems. Recommended prerequisite: 6.302.
M. A. Dahleh, A. Megretski, E. Frazzoli

6.245 Multivariable Control Systems
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.241 or 16.31
Units: 3-0-9
URL: http://web.mit.edu/6.245/www/index.html
______
Computer-aided design methodologies for synthesis of multivariable feedback control systems. Performance and robustness trade-offs. Model-based compensators; Q-parameterization; ill-posed optimization problems; dynamic augmentation; linear-quadratic optimization of controllers; H-infinity controller design; Mu-synthesis; model and compensator simplification; nonlinear effects. Computer-aided (MATLAB) design homework using models of physical processes.
A. Megretski

6.246, 6.247 Advanced Topics in Control
______

Graduate (Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Advanced study of topics in control. Specific focus varies from year to year.
Consult Department

6.248, 6.249 Advanced Topics in Numerical Methods
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Advanced study of topics in numerical methods. Specific focus varies from year to year.
Consult Department

6.251[J] Introduction to Mathematical Programming
______

Graduate (Fall)
(Same subject as15.081[J])
Prereq: 18.06
Units: 4-0-8
Lecture: TR1-2.30 (32-155) Recitation: F10 (36-156) or F12 (32-144)
______
Introduction to linear optimization and its extensions emphasizing both methodology and the underlying mathematical structures and geometrical ideas. Covers classical theory of linear programming as well as some recent advances in the field. Topics: simplex method; duality theory; sensitivity analysis; network flow problems; decomposition; integer programming; interior point algorithms for linear programming; and introduction to combinatorial optimization and NP-completeness.
J. N. Tsitsiklis, D. Bertsimas
Textbooks (Fall 2016)

6.252[J] Nonlinear Optimization
______

Graduate (Spring)
(Same subject as15.084[J])
Prereq: 18.06; 18.100A, 18.100B, or 18.100C
Units: 4-0-8
______
Unified analytical and computational approach to nonlinear optimization problems. Unconstrained optimization methods include gradient, conjugate direction, Newton, sub-gradient and first-order methods. Constrained optimization methods include feasible directions, projection, interior point methods, and Lagrange multiplier methods. Convex analysis, Lagrangian relaxation, nondifferentiable optimization, and applications in integer programming. Comprehensive treatment of optimality conditions and Lagrange multipliers. Geometric approach to duality theory. Applications drawn from control, communications, power systems, and resource allocation problems.
R. M. Freund, D. P. Bertsekas, G. Perakis

6.253 Convex Analysis and Optimization
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.06; 18.100A, 18.100B, or 18.100C
Units: 3-0-9
______
Core analytical issues of continuous optimization, duality, and saddle point theory, and development using a handful of unifying principles that can be easily visualized and readily understood. Discusses in detail the mathematical theory of convex sets and functions which are the basis for an intuitive, highly visual, geometrical approach to the subject. Convex optimization algorithms focus on large-scale problems, drawn from several types of applications, such as resource allocation and machine learning. Includes batch and incremental subgradient, cutting plane, proximal, and bundle methods.
D. P. Bertsekas

6.254 Game Theory with Engineering Applications
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.041B
Units: 4-0-8
______
Introduction to fundamentals of game theory and mechanism design with motivations for each topic drawn from engineering applications (including distributed control of wireline/wireless communication networks, transportation networks, pricing). Emphasis on the foundations of the theory, mathematical tools, as well as modeling and the equilibrium notion in different environments. Topics include normal form games, supermodular games, dynamic games, repeated games, games with incomplete/imperfect information, mechanism design, cooperative game theory, and network games.
A. Ozdaglar

6.255[J] Optimization Methods
______

Graduate (Fall)
(Same subject as15.093[J],IDS.200[J])
Prereq: 18.06
Units: 4-0-8
Lecture: TR2.30-4 (32-123) Recitation: W3 (66-168) or F1 (66-144) +final
______
Introduces the principal algorithms for linear, network, discrete, robust, nonlinear, dynamic optimization and optimal control. Emphasizes methodology and the underlying mathematical structures. Topics include the simplex method, network flow methods, branch and bound and cutting plane methods for discrete optimization, optimality conditions for nonlinear optimization, interior point methods for convex optimization, Newton's method, heuristic methods, and dynamic programming and optimal control methods.
D. Bertsimas, P. Parrilo
Textbooks (Fall 2016)

6.256 Algebraic Techniques and Semidefinite Optimization
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.251 or 6.255
Units: 3-0-9
______
Theory and computational techniques for optimization problems involving polynomial equations and inequalities with particular, emphasis on the connections with semidefinite optimization. Develops algebraic and numerical approaches of general applicability, with a view towards methods that simultaneously incorporate both elements, stressing convexity-based ideas, complexity results, and efficient implementations. Examples from several engineering areas, in particular systems and control applications. Topics include semidefinite programming, resultants/discriminants, hyperbolic polynomials, Groebner bases, quantifier elimination, and sum of squares.
P. Parrilo

6.260, 6.261 Advanced Topics in Communications
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Advanced study of topics in communications. Specific focus varies from year to year.
Consult Department

6.262 Discrete Stochastic Processes
______

Graduate (Spring)
Prereq: 6.041B, 6.431B or 18.204
Units: 4-0-8
______
Review of probability and laws of large numbers; Poisson counting process and renewal processes; Markov chains (including Markov decision theory), branching processes, birth-death processes, and semi-Markov processes; continuous-time Markov chains and reversibility; random walks, martingales, and large deviations; applications from queueing, communication, control, and operations research.
R. G. Gallager, V. W. S. Chan

6.263[J] Data-Communication Networks
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as16.37[J])
Prereq: 6.041B or 18.204
Units: 3-0-9
______
Provides an introduction to data networks with an analytic perspective, using telephone networks, wireless networks, optical networks, the Internet and data centers as primary applications. Presents basic tools for modeling and performance analysis accompanied by elementary, meaningful simulations. Develops insights for large networks by means of simple approximations. Draws upon concepts from queueing theory and optimization.
E. Modiano, D. Shah

6.265[J] Advanced Stochastic Processes
______

Graduate (Spring)
(Same subject as15.070[J])
Prereq: 6.431B, 15.085J, 18.100A, 18.100B, or 18.100Q
Units: 3-0-9
______
Analysis and modeling of stochastic processes. Topics include measure theoretic probability, martingales, filtration, and stopping theorems; elements of large deviations theory; Brownian motion and reflected Brownian motion; stochastic integration and Ito calculus; functional limit theorems. Applications to finance theory, insurance, queueing and inventory models.
D. Gamarnik, G. Bresler

6.267 Heterogeneous Networks: Architecture, Transport, Proctocols, and Management
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.041B or 6.042
Units: 4-0-8
______
Introduction to modern heterogeneous networks and the provision of heterogeneous services. Architectural principles, analysis, algorithmic techniques, performance analysis, and existing designs are developed and applied to understand current problems in network design and architecture. Begins with basic principles of networking. Emphasizes development of mathematical and algorithmic tools; applies them to understanding network layer design from the performance and scalability viewpoint. Concludes with network management and control, including the architecture and performance analysis of interconnected heterogeneous networks. Provides background and insight to understand current network literature and to perform research on networks with the aid of network design projects.
V. W. S. Chan, R. G. Gallager

6.268 Network Science and Models
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 6.041B, 18.06
Units: 3-0-9
______
Introduces the main mathematical models used to describe large networks and dynamical processes that evolve on networks. Static models of random graphs, preferential attachment, and other graph evolution models. Epidemic propagation, opinion dynamics, social learning, and inference in networks. Applications drawn from social, economic, natural, and infrastructure networks, as well as networked decision systems such as sensor networks.
J. N. Tsitsiklis, P. Jaillet


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Produced: 29-SEP-2016 06:37 AMFall 2016 Course 6: Electrical Engineering and Computer Science
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Course 6: Electrical Engineering and Computer Science
Fall 2016


Electronics, Computers, and Systems

6.301 Solid-State Circuits
______

Undergrad (Fall)
Prereq: 6.012
Units: 3-2-7
URL: http://web.mit.edu/6.301/www/
Lecture: TR1-2.30 (32-124)
______
Analysis and design of transistor circuits, based directly on the semiconductor physics and transistor circuit models developed in 6.012. High-frequency and low-frequency design calculations and simulation of multistage transistor circuits. Trans-linear circuits. Introduction to operational-amplifier design and application. Some previous laboratory experience assumed.
H. S. Lee
Textbooks (Fall 2016)

6.302 Feedback System Design
______

Undergrad (Spring)
(Subject meets with6.320)
Prereq: 6.003, 2.003, or 16.002
Units: 4-2-6
URL: http://web.mit.edu/6.302/www/
______
Learn-by-design introduction to continuous and discrete-time system modeling and feedback control. Topics include performance metrics; time- and frequency-domain model extraction and classical control; and basic state-space control. Students apply the control concepts in weekly labs and in a midterm project. Labs involve designing circuits and software, and using sensors and a high-performance microcontroller, to address control problems, such as positioning a motor- or propeller-actuated robot arm, reducing distortion in a PWM-based audio amplifier, eliminating field crosstalk for a magnetic-resonance imager, stabilizing magnetic levitation, balancing a two-wheel vehicle. Students taking graduate version complete additional assignments and an extra lab on observer-based state-space control. Intended for students who have previous laboratory experience with electronic systems.
J. D. Steinmeyer, J. K. White

6.320 Feedback System Design
(New)
______

Graduate (Spring)
(Subject meets with6.302)
Prereq: 6.003, 2.004, 2.04A, or 16.002
Units: 4-2-6
______
Learn-by-design introduction to continuous and discrete-time system modeling and feedback control. Topics include performance metrics; time- and frequency-domain model extraction and classical control; and basic state-space control. Students apply the control concepts in weekly labs and in a midterm project. Labs involve designing circuits and software, and using sensors and a high-performance microcontroller, to address control problems, such as positioning a motor- or propeller-actuated robot arm, reducing distortion in a PWM-based audio amplifier, eliminating field crosstalk for a magnetic-resonance imager, stabilizing magnetic levitation, balancing a two-wheel vehicle. Students taking graduate version complete additional assignments and an extra lab on observer-based state-space control. Intended for students who have previous laboratory experience with electronic systems. students taking graduate version complete additional assignments.
J. D. Steinmeyer, J. K. White

6.332, 6.333 Advanced Topics in Circuits
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
6.332: URL: https://www.eecs.mit.edu//academics-admissions/academic-information/subject-updates-st-2013?shib-logout=1
______
Advanced study of topics in circuits. Specific focus varies from year to year. Consult department for details.
Consult Department

6.334 Power Electronics
______

Graduate (Spring)
Prereq: 6.012
Units: 3-0-9
URL: http://web.mit.edu/course/6/6.334/
______
The application of electronics to energy conversion and control. Modeling, analysis, and control techniques. Design of power circuits including inverters, rectifiers, and dc-dc converters. Analysis and design of magnetic components and filters. Characteristics of power semiconductor devices. Numerous application examples, such as motion control systems, power supplies, and radio-frequency power amplifiers.
D. J. Perreault

6.335[J] Fast Methods for Partial Differential and Integral Equations
______

Graduate (Fall)
(Same subject as18.336[J])
Prereq: 6.336, 16.920, 18.085, 18.335, or permission of instructor
Units: 3-0-9
Lecture: MW9.30-11 (2-146)
______
Unified introduction to the theory and practice of modern, near linear-time, numerical methods for large-scale partial-differential and integral equations. Topics include preconditioned iterative methods; generalized Fast Fourier Transform and other butterfly-based methods; multiresolution approaches, such as multigrid algorithms and hierarchical low-rank matrix decompositions; and low and high frequency Fast Multipole Methods. Example applications include aircraft design, cardiovascular system modeling, electronic structure computation, and tomographic imaging.
C. Perez
No required or recommended textbooks

6.336[J] Introduction to Numerical Simulation
______

Graduate (Fall)
(Same subject as2.096[J],16.910[J])
Prereq: 18.03 or 18.06
Units: 3-3-6
Lecture: MW1-2.30 (32-141)
______
Introduction to computational techniques for the simulation of a large variety of engineering and physical systems. Applications are drawn from aerospace, mechanical, electrical, chemical engineering, biology, and materials science. Topics include mathematical formulations (techniques for automatic assembly of mathematical problems from physics' principles); sparse, direct and iterative solution techniques for linear systems; Newton and Homotopy methods for nonlinear problems; discretization methods for ordinary, time-periodic and partial differential equations; accelerated methods for integral equations; techniques for automatic generation of compact dynamical system models and model order reduction.
L. Daniel, J. K. White
No required or recommended textbooks

6.337[J] Introduction to Numerical Methods
______

Graduate (Spring)
(Same subject as18.335[J])
Prereq: 18.03 or 18.034; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.335
______
Advanced introduction to numerical linear algebra and other central algorithms of scientific computation. Topics include direct and iterative methods for linear systems, eigenvalue and QR/SVD factorizations, stability and accuracy, floating-point arithmetic, sparse matrices, preconditioning, and the memory considerations underlying modern linear-algebra software. Techniques for local and global nonlinear optimization, including quasi-Newton methods, trust regions, branch-and-bound, and multistart algorithms. Chebyshev approximations, numerical integration, and FFTs. A modern high-level language, Julia, is introduced for problem sets.
W. Shin

6.338[J] Parallel Computing
______

Graduate (Fall)
(Same subject as18.337[J])
Prereq: 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://beowulf.csail.mit.edu/18.337/index.html
Lecture: MW2-3.30 (4-237)
______
Interdisciplinary introduction to computing with Julia. Covers scientific computing and data analysis problems. Combines knowledge from computer science and computational science illustrating Julia's new approach to scientific computing. Sample scientific computing topics include dense and sparse linear algebra, Fourier transforms, data handling, and N-body problems. Provides direct experience with programming traditional-style supercomputing as well as working with modern cloud computing stacks.
A. Edelman
No textbook information available

6.339[J] Numerical Methods for Partial Differential Equations
______

Graduate (Fall)
(Same subject as2.097[J],16.920[J])
Prereq: 18.03 or 18.06
Units: 3-0-9
Lecture: MW9.30-11 (4-163)
______
Covers the fundamentals of modern numerical techniques for a wide range of linear and nonlinear elliptic, parabolic, and hyperbolic partial differential and integral equations. Topics include mathematical formulations; finite difference, finite volume, finite element, and boundary element discretization methods; and direct and iterative solution techniques. The methodologies described form the foundation for computational approaches to engineering systems involving heat transfer, solid mechanics, fluid dynamics, and electromagnetics. Computer assignments requiring programming.
Q. Wang, J. K. White
No textbook information available

6.341 Discrete-Time Signal Processing
______

Graduate (Fall)
Prereq: 6.011
Units: 4-0-8
URL: http://web.mit.edu/6.341/www/
Lecture: TR11-12.30 (32-124) Recitation: F11 (4-145) or F2 (4-145) +final
______
Representation, analysis, and design of discrete time signals and systems. Decimation, interpolation, and sampling rate conversion. Noise shaping. Flowgraph structures for DT systems. Lattice filters. Time- and frequency-domain design techniques for IIR and FIR filters. Parametric signal modeling, linear prediction, and the relation to lattice filters. Discrete Fourier transform (DFT). Computation of the DFT including FFT algorithms. Short-time Fourier analysis and relation to filter banks. Multirate techniques. Perfect reconstruction filter banks and their relation to wavelets.
A. V. Oppenheim, J. Ward
Textbooks (Fall 2016)

6.344 Digital Image Processing
______

Graduate (Spring)
Prereq: 6.003, 6.041B
Units: 3-0-9
______
Digital images as two-dimensional signals. Digital signal processing theories used for digital image processing, including one-dimensional and two-dimensional convolution, Fourier transform, discrete Fourier transform, and discrete cosine transform. Image processing basics. Image enhancement. Image restoration. Image coding and compression. Video processing including video coding and compression. Additional topics including digital high-definition television systems.
J. S. Lim

6.345[J] Automatic Speech Recognition
______

Graduate (Spring)
(Same subject asHST.728[J])
Prereq: 6.003, 6.041, or permission of instructor
Units: 3-1-8
URL: http://courses.csail.mit.edu/6.345/
______
Introduces the rapidly developing fields of automatic speech recognition and spoken language processing. Topics include acoustic theory of speech production and perception, acoustic-phonetics, signal representation, acoustic and language modeling, search, hidden Markov modeling, robustness, adaptation, discriminative and alternative approaches. Lectures interspersed with theory and applications. Assignments include problems, laboratory exercises, and a term project. 4 Engineering Design Points.
V. W. Zue, J. R. Glass

6.347, 6.348 Advanced Topics in Signals and Systems
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
6.348: URL: http://www.eecs.mit.edu/academics-admissions/academic-information/subject-updates-ft-2014
______
Advanced study of topics in signals and systems. Specific focus varies from year to year.
Consult Department

6.374 Analysis and Design of Digital Integrated Circuits
______

Graduate (Fall)
Prereq: 6.012, 6.004
Units: 3-3-6
Lecture: TR11-12.30 (34-302) Lab: TBA
______
Device and circuit level optimization of digital building blocks. MOS device models including Deep Sub-Micron effects. Circuit design styles for logic, arithmetic, and sequential blocks. Estimation and minimization of energy consumption. Interconnect models and parasitics, device sizing and logical effort, timing issues (clock skew and jitter), and active clock distribution techniques. Memory architectures, circuits (sense amplifiers), and devices. Testing of integrated circuits. Extensive custom and standard cell layout and simulation in design projects and software labs.
V. Sze, A. P. Chandrakasan
Textbooks (Fall 2016)

6.375 Complex Digital Systems Design
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.004
Units: 5-5-2
______
Introduction to the design and implementation of large-scale digital systems using hardware description languages and high-level synthesis tools in conjunction with standard commercial electronic design automation (EDA) tools. Emphasizes modular and robust designs, reusable modules, correctness by construction, architectural exploration, meeting area and timing constraints, and developing functional field-programmable gate array (FPGA) prototypes. Extensive use of CAD tools in weekly labs serve as preparation for a multi-person design project on multi-million gate FPGAs. Enrollment may be limited.
Arvind

Probabilistic Systems and Communication

6.431A Introduction to Probability I
(New)
______

Graduate (Fall, Spring); first half of term
(Subject meets with6.041A)
Prereq: Calculus II (GIR)
Units: 2-0-4
Ends Oct 21. Lecture: MW12 (34-101) Recitation: TR11 (24-121) or TR12 (24-121) or TR1 (24-121) or TR2 (24-121)
______
Provides an introduction to probability theory and the modeling and analysis of probabilistic systems. Probabilistic models, conditional probability. Discrete and continuous random variables. Expectation and conditional expectation. Limit Theorems. Students taking graduate version complete additional assignments.
P. Jaillet, J. N. Tsitsiklis
No textbook information available

6.431B Introduction to Probability II
(New)
______

Graduate (Fall, Spring); second half of term
(Subject meets with6.041B)
Prereq: 6.431A
Units: 2-0-4
Begins Oct 24. Lecture: MW12 (34-101) Recitation: TR11 (24-121) or TR12 (24-121) or TR1 (24-121) or TR2 (24-121) +final
______
Further topics in probability. Bayesian estimation and hypothesis testing. Elements of statistical inference. Bernoulli and Poisson processes. Markov chains. Students taking graduate version complete additional assignments.
P. Jaillet, J. N. Tsitsiklis
No textbook information available

6.434[J] Statistics for Engineers and Scientists
______

Graduate (Fall)
(Same subject as16.391[J])
Prereq: Calculus II (GIR), 18.06, 6.431B, or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (8-205)
______
Rigorous introduction to fundamentals of statistics motivated by engineering applications. Topics include exponential families, order statistics, sufficient statistics, estimation theory, hypothesis testing, measures of performance, notions of optimality, analysis of variance (ANOVA), simple linear regression, and selected topics.
M. Win, J. N. Tsitsiklis
No textbook information available

6.436[J] Fundamentals of Probability
______

Graduate (Fall)
(Same subject as15.085[J])
Prereq: Calculus II (GIR)
Units: 4-0-8
Lecture: MW2.30-4 (E51-345) Recitation: F2 (66-144) +final
______
Introduction to probability theory. Probability spaces and measures. Discrete and continuous random variables. Conditioning and independence. Multivariate normal distribution. Abstract integration, expectation, and related convergence results. Moment generating and characteristic functions. Bernoulli and Poisson process. Finite-state Markov chains. Convergence notions and their relations. Limit theorems. Familiarity with elementary notions in probability and real analysis is desirable.
J. N. Tsitsiklis, D. Gamarnik
Textbooks (Fall 2016)

6.437 Inference and Information
______

Graduate (Spring)
Prereq: 6.008, 6.041B, or 6.436
Units: 4-0-8
______
Introduction to principles of Bayesian and non-Bayesian statistical inference. Hypothesis testing and parameter estimation, sufficient statistics; exponential families. EM agorithm. Log-loss inference criterion, entropy and model capacity. Kullback-Leibler distance and information geometry. Asymptotic analysis and large deviations theory. Model order estimation; nonparametric statistics. Computational issues and approximation techniques; Monte Carlo methods. Selected special topics such as universal prediction and compression.
P. Golland, G. W. Wornell

6.438 Algorithms for Inference
______

Graduate (Fall)
Prereq: 6.008, 6.041B, or 6.436; 18.06
Units: 4-0-8
Lecture: TR9.30-11 (4-370) Recitation: F10 (8-119) or F11 (8-119) +final
______
Introduction to statistical inference with probabilistic graphical models. Directed and undirected graphical models, and factor graphs, over discrete and Gaussian distributions; hidden Markov models, linear dynamical systems. Sum-product and junction tree algorithms; forward-backward algorithm, Kalman filtering and smoothing. Min-sum and Viterbi algorithms. Variational methods, mean-field theory, and loopy belief propagation. Particle methods and filtering. Building graphical models from data, including parameter estimation and structure learning; Baum-Welch and Chow-Liu algorithms. Selected special topics.
P. Golland, G. W. Wornell, D. Shah
No textbook information available

6.440 Essential Coding Theory
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.006, 6.045
Units: 3-0-9
______
Introduces the theory of error-correcting codes. Focuses on the essential results in the area, taught from first principles. Special focus on results of asymptotic or algorithmic significance. Principal topics include construction and existence results for error-correcting codes; limitations on the combinatorial performance of error-correcting codes; decoding algorithms; and applications to other areas of mathematics and computer science.
Staff

6.441 Information Theory
______

Graduate (Spring)
Prereq: 6.041B
Units: 3-0-9
URL: http://web.mit.edu/6.441/www/
______
Mathematical definitions of information measures, convexity, continuity, and variational properties. Lossless source coding; variable-length and block compression; Slepian-Wolf theorem; ergodic sources and Shannon-McMillan theorem. Hypothesis testing, large deviations and I-projection. Fundamental limits of block coding for noisy channels: capacity, dispersion, finite blocklength bounds. Coding with feedback. Joint source-channel problem. Rate-distortion theory, vector quantizers. Advanced topics include Gelfand-Pinsker problem, multiple access channels, broadcast channels (depending on available time).
M. Medard, Y. Polyanskiy, L. Zheng

6.442 Optical Networks
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.041B or 6.042
Units: 3-0-9
______
Introduces the fundamental and practical aspects of optical network technology, architecture, design and analysis tools and techniques. The treatment of optical networks are from the architecture and system design points of view. Optical hardware technologies are introduced and characterized as fundamental network building blocks on which optical transmission systems and network architectures are based. Beyond the Physical Layer, the higher network layers (Media Access Control, Network and Transport Layers) are treated together as integral parts of network design. Performance metrics, analysis and optimization techniques are developed to help guide the creation of high performance complex optical networks.
V. W. S. Chan

6.443[J] Quantum Information Science
______

Graduate (Spring)
(Same subject as8.371[J],18.436[J])
Prereq: 18.435
Units: 3-0-9
______
Examines quantum computation and quantum information. Topics include quantum circuits, the quantum Fourier transform and search algorithms, the quantum operations formalism, quantum error correction, Calderbank-Shor-Steane and stabilizer codes, fault tolerant quantum computation, quantum data compression, quantum entanglement, capacity of quantum channels, and quantum cryptography and the proof of its security. Prior knowledge of quantum mechanics required.
I. Chuang

6.450 Principles of Digital Communication
______

Graduate (Fall)
Prereq: 6.011
Units: 3-0-9
Lecture: MW9.30-11 (36-155) +final
______
Communication sources and channels; data compression; entropy and the AEP; Lempel-Ziv universal coding; scalar and vector quantization; L2 waveforms; signal space and its representation by sampling and other expansions; aliasing; the Nyquist criterion; PAM and QAM modulation; Gaussian noise and random processes; detection and optimal receivers; fading channels and wireless communication; introduction to communication system design.
M. Medard, L. Zheng
Textbooks (Fall 2016)

6.452 Principles of Wireless Communication
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.450
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduction to design, analysis, and fundamental limits of wireless transmission systems. Wireless channel and system models; fading and diversity; resource management and power control; multiple-antenna and MIMO systems; space-time codes and decoding algorithms; multiple-access techniques and multiuser detection; broadcast codes and precoding; cellular and ad-hoc network topologies; OFDM and ultrawideband systems; architectural issues.
G. W. Wornell, L. Zheng

6.453 Quantum Optical Communication
______

Graduate (Fall)
Prereq: 6.011, 18.06
Units: 3-0-9
Lecture: TR1-2.30 (8-205)
______
Quantum optics: Dirac notation quantum mechanics; harmonic oscillator quantization; number states, coherent states, and squeezed states; radiation field quantization and quantum field propagation; P-representation and classical fields. Linear loss and linear amplification: commutator preservation and the Uncertainty Principle; beam splitters; phase-insensitive and phase-sensitive amplifiers. Quantum photodetection: direct detection, heterodyne detection, and homodyne detection. Second-order nonlinear optics: phasematched interactions; optical parametric amplifiers; generation of squeezed states, photon-twin beams, non-classical fourth-order interference, and polarization entanglement. Quantum systems theory: optimum binary detection; quantum precision measurements; quantum cryptography; and quantum teleportation.
J. H. Shapiro
No required or recommended textbooks

6.454 Graduate Seminar in Area I
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
URL: http://web.mit.edu/6.454/www/
______
Student-run advanced graduate seminar with focus on topics in communications, control, signal processing, optimization. Participants give presentations outside of their own research to expose colleagues to topics not covered in the usual curriculum. Recent topics have included compressed sensing, MDL principle, communication complexity, linear programming decoding, biology in EECS, distributed hypothesis testing, algorithms for random satisfaction problems, and cryptogaphy. Open to advanced students from all areas of EECS. Limited to 12.
L. Zheng, D. Shah

6.456 Array Processing
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.341; 2.687, or 6.011 and 18.06
Units: 3-2-7
Subject Cancelled Subject Cancelled
______
Adaptive and non-adaptive processing of signals received at arrays of sensors. Deterministic beamforming, space-time random processes, optimal and adaptive algorithms, and the sensitivity of algorithm performance to modeling errors and limited data. Methods of improving the robustness of algorithms to modeling errors and limited data are derived. Advanced topics include an introduction to matched field processing and physics-based methods of estimating signal statistics. Homework exercises providing the opportunity to implement and analyze the performance of algorithms in processing data supplied during the course.
Staff

Bioelectrical Engineering

6.503 Foundations of Algorithms and Computational Techniques in Systems Biology
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with6.581[J],20.482[J])
Prereq: 6.021, 6.034, 6.046, 6.336, 18.417, or permission of instructor
Units: 3-0-9
______
Illustrates computational approaches to solving problems in systems biology. Uses a series of case studies to demonstrate how an effective match between the statement of a biological problem and the selection of an appropriate algorithm or computational technique can lead to fundamental advances. Covers several discrete and numerical algorithms used in simulation, feature extraction, and optimization for molecular, network, and systems models in biology. Students taking graduate version complete additional assignments.
B. Tidor, J. K. White

6.521[J] Cellular Neurophysiology
______

Graduate (Fall)
(Same subject as2.794[J],20.470[J],HST.541[J])
(Subject meets with2.791[J],6.021[J],20.370[J])
Prereq: Physics II (GIR); 18.03; 2.005, 6.002, 6.003, 6.071, 10.301, 20.110, or permission of instructor
Units: 5-2-5
Lecture: MWF10 (32-144) Lab: TBA Recitation: T12 (34-303) or T4 (34-302) +final
______
Meets with undergraduate subject 6.021J. Requires the completion of more advanced home problems and/or an additional project.
J. Han, T. Heldt
Textbooks (Fall 2016)

6.522[J] Quantitative Physiology: Organ Transport Systems
______

Graduate (Spring)
(Same subject as2.796[J])
(Subject meets with2.792[J],6.022[J],HST.542[J])
Prereq: 2.006 or 6.013; 6.021
Units: 4-2-6
______
Application of the principles of energy and mass flow to major human organ systems. Mechanisms of regulation and homeostasis. Anatomical, physiological and pathophysiological features of the cardiovascular, respiratory and renal systems. Systems, features and devices that are most illuminated by the methods of physical sciences. Laboratory work includes some animal studies. Students taking graduate version complete additional assignments.
Application of the principles of energy and mass flow to major human organ systems. Mechanisms of regulation and homeostasis. Anatomical, physiological and pathophysiological features of the cardiovascular, respiratory and renal systems. Systems, features and devices that are most illuminated by the methods of physical sciences. Laboratory work includes some animal studies. Students taking graduate version complete additional assignments.
T. Heldt, R. G. Mark, C. M. Stultz

6.524[J] Molecular, Cellular, and Tissue Biomechanics
______

Graduate (Fall)
(Same subject as2.798[J],3.971[J],10.537[J],20.410[J])
Prereq: Biology (GIR); 2.002, 2.006, 6.013, 10.301, or 10.302
Units: 3-0-9
Lecture: TR10.30-12 (2-143)
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, K. J. Van Vliet
No textbook information available

6.525[J] Medical Device Design
______

Graduate (Fall)
(Same subject as2.75[J],HST.552[J])
(Subject meets with2.750[J],6.025[J])
Prereq: 2.72, 6.101, 6.111, 6.115, 22.071, or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (3-270)
______
Application of mechanical and electrical engineering fundamentals to the design of medical devices that address clinical needs. Students work in small teams on a major project to translate a clinical challenge into a proof-of-concept prototype device. Students conduct user analysis, develop design specifications, and follow a structured process to cultivate creative designs and apply analytical techniques to optimize them. They deepen their understanding of art and intellectual property by researching prior representations. Develops practical skills in prototyping and testing as well as project management. Includes lectures, problem sets and exams that focus on design fundamentals. Instruction and practice in written and oral communication provided. Students taking graduate version complete additional assignments. Enrollment limited.
A. H. Slocum, G. Hom
No required or recommended textbooks

6.542[J] Laboratory on the Physiology, Acoustics, and Perception of Speech
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as24.966[J],HST.712[J])
Prereq: Permission of instructor
Units: 2-2-8
______
Experimental investigations of speech processes. Topics: measurement of articulatory movements; measurements of pressures and airflows in speech production; computer-aided waveform analysis and spectral analysis of speech; synthesis of speech; perception and discrimination of speechlike sounds; speech prosody; models for speech recognition; speech development; and other topics. Recommended prerequisites: 6.002 or 18.03.
L. D. Braida, S. Shattuck-Hufnagel

6.544, 6.545 Advanced Topics in BioEECS
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Advanced study of topics in BioEECS. Specific focus varies from year to year. Consult department for details.
Consult Department

6.552[J] Signal Processing by the Auditory System: Perception
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject asHST.716[J])
Prereq: 6.003; 6.041B or 6.431B; or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Studies information processing performance of the human auditory system in relation to current physiological knowledge. Examines mathematical models for the quantification of auditory-based behavior and the relation between behavior and peripheral physiology, reflecting the tono-topic organization and stochastic responses of the auditory system. Mathematical models of psychophysical relations, incorporating quantitative knowledge of physiological transformations by the peripheral auditory system.
L. D. Braida

6.555[J] Biomedical Signal and Image Processing
______

Graduate (Spring)
(Same subject as16.456[J],HST.582[J])
Prereq: 6.003, 2.004, 16.004, or 18.085
Units: 3-4-5
URL: http://web.mit.edu/6.555/www/
______
Fundamentals of digital signal processing with particular emphasis on problems in biomedical research and clinical medicine. Basic principles and algorithms for data acquisition, imaging, filtering, and feature extraction. Laboratory projects provide practical experience in processing physiological data, with examples from cardiology, speech processing, and medical imaging.
J. Greenberg, E. Adalsteinsson, W. Wells

6.556[J] Data Acquisition and Image Reconstruction in MRI
______

Graduate (Fall)
(Same subject asHST.580[J])
Prereq: 6.011
Units: 3-0-9
Lecture: TR11-12.30 (1-150)
______
Applies analysis of signals and noise in linear systems, sampling, and Fourier properties to magnetic resonance (MR) imaging acquisition and reconstruction. Provides adequate foundation for MR physics to enable study of RF excitation design, efficient Fourier sampling, parallel encoding, reconstruction of non-uniformly sampled data, and the impact of hardware imperfections on reconstruction performance. Surveys active areas of MR research. Assignments include Matlab-based work with real data. Includes visit to a scan site for human MR studies.
E. Adalsteinsson
No textbook information available

6.557[J] Biomolecular Feedback Systems
______

Graduate (Spring)
(Same subject as2.18[J])
(Subject meets with2.180[J],6.027[J])
Prereq: 18.03, Biology (GIR), or permission of instructor
Units: 3-0-9
______
Comprehensive introduction to dynamics and control of biomolecular systems with emphasis on design/analysis techniques from control theory. Provides a review of biology concepts, regulation mechanisms, and models. Covers basic enabling technologies, engineering principles for designing biological functions, modular design techniques, and design limitations. Students taking graduate version complete additional assignments.
D. Del Vecchio, R. Weiss

6.561[J] Fields, Forces, and Flows in Biological Systems
______

Graduate (Fall)
(Same subject as2.795[J],10.539[J],20.430[J])
Prereq: 6.013, 2.005, 10.302, or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (32-124)
______
Molecular diffusion, diffusion-reaction, conduction, convection in biological systems; fields in heterogeneous media; electrical double layers; Maxwell stress tensor, electrical forces in physiological systems. Fluid and solid continua: equations of motion useful for porous, hydrated biological tissues. Case studies of membrane transport, electrode interfaces, electrical, mechanical, and chemical transduction in tissues, convective-diffusion/reaction, electrophoretic, electroosmotic flows in tissues/MEMs, and ECG. Electromechanical and physicochemical interactions in cells and biomaterials; musculoskeletal, cardiovascular, and other biological and clinical examples.
M. Bathe, A. J. Grodzinsky
Textbooks (Fall 2016)

6.580[J] Principles of Synthetic Biology
______

Undergrad (Fall)
(Same subject as20.305[J])
(Subject meets with6.589[J],20.405[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (9-057) +final
______
Introduces the basics of synthetic biology, including quantitative cellular network characterization and modeling. Considers the discovery and genetic factoring of useful cellular activities into reusable functions for design. Emphasizes the principles of biomolecular system design and diagnosis of designed systems. Illustrates cutting-edge applications in synthetic biology and enhances skills in analysis and design of synthetic biological applications. Students taking graduate version complete additional assignments.
R. Weiss
No textbook information available

6.581[J] Foundations of Algorithms and Computational Techniques in Systems Biology
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as20.482[J])
(Subject meets with6.503)
Prereq: 6.021, 6.034, 6.046, 6.336, 18.417, or permission of instructor
Units: 3-0-9
______
Illustrates computational approaches to solving problems in systems biology. Uses a series of case studies to demonstrate how an effective match between the statement of a biological problem and the selection of an appropriate algorithm or computational technique can lead to fundamental advances. Covers several discrete and numerical algorithms used in simulation, feature extraction, and optimization for molecular, network, and systems models in biology. Students taking graduate version complete additional assignments.
B. Tidor, J. K. White

6.589[J] Principles of Synthetic Biology
______

Graduate (Fall)
(Same subject as20.405[J])
(Subject meets with6.580[J],20.305[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (9-057) +final
______
Introduces the basics of synthetic biology, including quantitative cellular network characterization and modeling. Considers the discovery and genetic factoring of useful cellular activities into reusable functions for design. Emphasizes the principles of biomolecular system design and diagnosis of designed systems. Illustrates cutting-edge applications in synthetic biology and enhances skills in analysis and design of synthetic biological applications. Students taking graduate version complete additional assignments.
R. Weiss
No textbook information available

Electrodynamics

6.602 Fundamentals of Photonics
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with6.621)
Prereq: 2.71, 6.013, or 8.07
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Covers the fundamentals of optics and the interaction of light and matter, leading to devices such as light emitting diodes, optical amplifiers, and lasers. Topics include classical ray, wave, beam, and Fourier optics; Maxwell's electromagnetic waves; resonators; quantum theory of photons; light-matter interaction; laser amplification; lasers; and semiconductors optoelectronics. Students taking graduate version complete additional assignments.
D. R. Englund

6.621 Fundamentals of Photonics
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with6.602)
Prereq: 2.71, 6.013, or 8.07
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Covers the fundamentals of optics and the interaction of light and matter, leading to devices such as light emitting diodes, optical amplifiers, and lasers. Topics include classical ray, wave, beam, and Fourier optics; Maxwell's electromagnetic waves; resonators; quantum theory of photons; light-matter interaction; laser amplification; lasers; and semiconductors optoelectronics. Students taking graduate version complete additional assignments.
D. R. Englund

6.630 Electromagnetics
______

Graduate (Fall)
Prereq: 6.003 or 6.007
Units: 4-0-8
URL: http://cetaweb.mit.edu/6.630/
Lecture: WF2.30-4 (32-144)
______
Explores electromagnetic phenomena in modern applications, including wireless and optical communications, circuits, computer interconnects and peripherals, microwave communications and radar, antennas, sensors, micro-electromechanical systems, and power generation and transmission. Fundamentals include quasistatic and dynamic solutions to Maxwell's equations; waves, radiation, and diffraction; coupling to media and structures; guided and unguided waves; modal expansions; resonance; acoustic analogs; and forces, power, and energy.
L. Daniel, M. R. Watts
Textbooks (Fall 2016)

6.631 Optics and Photonics
______

Graduate (Fall)
Prereq: 6.013 or 8.07
Units: 3-0-9
Lecture: MW3-4.30 (36-372) +final
______
Introduction to fundamental concepts and techniques of optics, photonics, and fiber optics. Review of Maxwell's equations, light propagation, and reflection from dielectrics mirrors and filters. Interferometers, filters, and optical imaging systems. Fresnel and Fraunhoffer diffraction theory. Propagation of Gaussian beams and laser resonator design. Optical waveguides and optical fibers. Optical waveguide and photonic devices.
J. G. Fujimoto
Textbooks (Fall 2016)

6.632 Electromagnetic Wave Theory
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.013, 6.630, or 8.07
Units: 3-0-9
______
Solutions to Maxwell equations and physical interpretation. Topics include waves in media, equivalence principle, duality and complementarity, Huygens' principle, Fresnel and Fraunhofer diffraction, radiation and dyadic Green's functions, scattering, metamaterials, and plasmonics, mode theory, dielectric waveguides, and resonators. Examples deal with limiting cases of electromagnetic theory, multi-port elements, filters and antennas. Discusses current topics in microwave and photonic devices.
M. R. Watts

6.634[J] Nonlinear Optics
______

Graduate (Spring)
(Same subject as8.431[J])
Prereq: 6.013 or 8.07
Units: 3-0-9
______
Techniques of nonlinear optics with emphasis on fundamentals for research and engineering in optics, photonics, and spectroscopy. Electro optic modulators, harmonic generation, and frequency conversion devices. Nonlinear effects in optical fibers including self-phase modulation, nonlinear wave propagation, and solitons. Interaction of light with matter, laser operation, density matrix techniques, nonlinear spectroscopies, and femtosecond optics.
J. G. Fujimoto

6.637 Optical Signals, Devices, and Systems
______

Graduate (Fall)
(Subject meets with6.161)
Prereq: 6.003
Units: 3-0-9
Lecture: TR2.30-4 (34-304) Lab: TBA
______
Principles of operation and applications of devices and systems for optical signal generation, transmission, detection, storage, processing and display. Topics include review of the basic properties of electromagnetic waves; coherence and interference; diffraction and holography; Fourier optics; coherent and incoherent imaging and signal processing systems; optical properties of materials; lasers and LEDs; electro-optic and acousto-optic light modulators; photorefractive and liquid-crystal light modulation; spatial light modulators and displays; optical waveguides and fiber-optic communication systems; photodetectors; 2-D and 3-D optical storage technologies; adaptive optical systems; role of optics in next-generation computers. Student research paper on a specific contemporary topic required. Recommended prerequisites: 6.007 or 8.03.
C. Warde
No textbook information available

6.641 Electromagnetic Fields, Forces, and Motion
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.013
Units: 4-0-8
______
Electric and magnetic quasistatic forms of Maxwell's equations applied to dielectric, conduction, and magnetization boundary value problems. Electromagnetic forces, force densities, and stress tensors, including magnetization and polarization. Thermodynamics of electromagnetic fields, equations of motion, and energy conservation. Applications to synchronous, induction, and commutator machines; sensors and transducers; microelectromechanical systems; propagation and stability of electromechanical waves; and charge transport phenomena.
J. H. Lang

6.642 Continuum Electromechanics
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.641 or permission of instructor
Units: 4-0-8
______
Laws, approximations, and relations of continuum mechanics. Mechanical and electromechanical transfer relations. Statics and dynamics of electromechanical systems having a static equilibrium. Electromechanical flows. Field coupling with thermal and molecular diffusion. Electrokinetics. Streaming interactions. Application to materials processing, magnetohydrodynamic and electrohydrodynamic pumps and generators, ferrohydrodynamics, physiochemical systems, heat transfer, continuum feedback control, electron beam devices, and plasma dynamics.
Staff

6.644, 6.645 Advanced Topics in Applied Physics
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled 6.645 Cancelled
______
Advanced study of topics in applied physics. Specific focus varies from year to year. Consult department for details.
Consult Department

6.685 Electric Machines
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.061 or 6.690; or permission of instructor
Units: 3-0-9
______
Treatment of electromechanical transducers, rotating and linear electric machines. Lumped-parameter electromechanics. Power flow using Poynting's theorem, force estimation using the Maxwell stress tensor and Principle of virtual work. Development of analytical techniques for predicting device characteristics: energy conversion density, efficiency; and of system interaction characteristics: regulation, stability, controllability, and response. Use of electric machines in drive systems. Problems taken from current research.
J. L. Kirtley, Jr.

6.690 Introduction to Electric Power Systems
______

Not offered academic year 2017-2018Graduate (Spring)
(Subject meets with6.061)
Prereq: 6.002, 6.013
Units: 3-0-9
______
Electric circuit theory with application to power handling electric circuits. Modeling and behavior of electromechanical devices, including magnetic circuits, motors, and generators. Operational fundamentals of synchronous, induction and DC machinery. Interconnection of generators and motors with electric power transmission and distribution circuits. Power generation, including alternative and sustainable sources. Students taking graduate version complete additional assignments.
J. L. Kirtley, Jr.

6.695[J] Engineering, Economics and Regulation of the Electric Power Sector
______

Graduate (Spring)
(Same subject as15.032[J],IDS.505[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Provides an in-depth and interdisciplinary look at electric power systems, focusing on regulation as the link among engineering, economic, legal, and environmental viewpoints. Topics include electricity markets, incentive regulation of network utilities, retail competition, tariff design, distributed generation, rural electrification, multinational electricity markets, environmental impacts, future of utilities and strategic sustainability issues under both traditional and competitive regulatory frameworks. Background in policy, microeconomics, or engineering desirable.
C. Vergara

Solid-State Materials and Devices

6.701 Introduction to Nanoelectronics
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with6.719)
Prereq: 6.003
Units: 4-0-8
Subject Cancelled Subject Cancelled
______
Transistors at the nanoscale. Quantization, wavefunctions, and Schrodinger's equation. Introduction to electronic properties of molecules, carbon nanotubes, and crystals. Energy band formation and the origin of metals, insulators and semiconductors. Ballistic transport, Ohm's law, ballistic versus traditional MOSFETs, fundamental limits to computation.
M. A. Baldo

6.717[J] Design and Fabrication of Microelectromechanical Systems
______

Not offered academic year 2016-2017Undergrad (Spring)
(Same subject as2.374[J])
(Subject meets with2.372[J],6.777[J])
Prereq: 6.003 or 2.003, Physics II (GIR); or permission of instructor
Units: 3-0-9
______
Provides an introduction to microsystem design. Covers material properties, microfabrication technologies, structural behavior, sensing methods, electromechanical actuation, thermal actuation and control, multi-domain modeling, noise, and microsystem packaging. Applies microsystem modeling, and manufacturing principles to the design and analysis a variety of microscale sensors and actuators (e.g., optical MEMS, bioMEMS, and inertial sensors). Emphasizes modeling and simulation in the design process. Students taking the graduate version complete additional assignments.
Staff

6.719 Nanoelectronics
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with6.701)
Prereq: 6.003
Units: 4-0-8
Subject Cancelled Subject Cancelled
______
Meets with undergraduate subject 6.701, but requires the completion of additional/different homework assignments and or projects. See subject description under 6.701.
M. A. Baldo

6.720[J] Integrated Microelectronic Devices
______

Graduate (Fall)
(Same subject as3.43[J])
Prereq: 6.012 or 3.42
Units: 4-0-8
Lecture: MWRF10 (66-144) +final
______
Covers physics of microelectronic semiconductor devices for integrated circuit applications. Topics include semiconductor fundamentals, p-n junction, metal-oxide semiconductor structure, metal-semiconductor junction, MOS field-effect transistor, and bipolar junction transistor. Studies modern nanoscale devices, including electrostatic scaling, materials beyond Si, carrier transport from the diffusive to the ballistic regime. Emphasizes physical understanding of device operation through energy band diagrams and short-channel MOSFET device design. Includes device modeling exercises. Familiarity with MATLAB required. 2 Engineering Design Points.
D. A. Antoniadis, J. A. del Alamo, H. L. Tuller
No textbook information available

6.728 Applied Quantum and Statistical Physics
______

Graduate (Fall)
Prereq: 6.003, 18.06
Units: 4-0-8
Lecture: WF11-12.30 (26-328) Recitation: M11 (26-328) +final
______
Elementary quantum mechanics and statistical physics. Introduces applied quantum physics. Emphasizes experimental basis for quantum mechanics. Applies Schrodinger's equation to the free particle, tunneling, the harmonic oscillator, and hydrogen atom. Variational methods. Elementary statistical physics; Fermi-Dirac, Bose-Einstein, and Boltzmann distribution functions. Simple models for metals, semiconductors, and devices such as electron microscopes, scanning tunneling microscope, thermonic emitters, atomic force microscope, and more.
P. L. Hagelstein
Textbooks (Fall 2016)

6.730 Physics for Solid-State Applications
______

Graduate (Spring)
Prereq: 6.013, 6.728
Units: 5-0-7
______
Classical and quantum models of electrons and lattice vibrations in solids, emphasizing physical models for elastic properties, electronic transport, and heat capacity. Crystal lattices, electronic energy band structures, phonon dispersion relations, effective mass theorem, semiclassical equations of motion, electron scattering and semiconductor optical properties. Band structure and transport properties of selected semiconductors. Connection of quantum theory of solids with quasi-Fermi levels and Boltzmann transport used in device modeling.
Q. Hu, R. Ram

6.731 Semiconductor Optoelectronics: Theory and Design
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.728, 6.012
Units: 3-0-9
______
Focuses on the physics of the interaction of photons with semiconductor materials. Uses the band theory of solids to calculate the absorption and gain of semiconductor media; and uses rate equation formalism to develop the concepts of laser threshold, population inversion, and modulation response. Presents theory and design for photodetectors, solar cells, modulators, amplifiers, and lasers. Introduces noise models for semiconductor devices, and applications of optoelectronic devices to fiber optic communications.
R. J. Ram

6.732 Physics of Solids
______

Graduate (Fall)
Prereq: 6.730 or 8.231
Units: 4-0-8
Lecture: MWF11 (34-303) Recitation: F10 (34-303)
______
Continuation of 6.730 emphasizing applications-related physical issues in solids. Topics include: electronic structure and energy band diagrams of semiconductors, metals, and insulators; Fermi surfaces; dynamics of electrons under electric and magnetic fields; classical diffusive transport phenomena such as electrical and thermal conduction and thermoelectric phenomena; quantum transport in tunneling and ballistic devices; optical properties of metals, semiconductors, and insulators; impurities and excitons; photon-lattice interactions; Kramers-Kronig relations; optoelectronic devices based on interband and intersubband transitions; magnetic properties of solids; exchange energy and magnetic ordering; magneto-oscillatory phenomena; quantum Hall effect; superconducting phenomena and simple models.
Q. Hu
No textbook information available

6.735, 6.736 Advanced Topics in Materials, Devices, and Nanotechnology
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Advanced study of topics in materials, devices, and nanotechnology. Specific focus varies from year to year.
Consult Department

6.774 Physics of Microfabrication: Front End Processing
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 6.152
Units: 3-0-9
______
Presents advanced physical models and practical aspects of front-end microfabrication processes, such as oxidation, diffusion, ion implantation, chemical vapor deposition, atomic layer deposition, etching, and epitaxy. Covers topics relevant to CMOS, bipolar, and optoelectronic device fabrication, including high k gate dielectrics, gate etching, implant-damage enhanced diffusion, advanced metrology, stress effects on oxidation, non-planar and nanowire device fabrication, SiGe and fabrication of process-induced strained Si. Exposure to CMOS process integration concepts, and impacts of processing on device characteristics. Students use modern process simulation tools.
J. L. Hoyt, L. R. Reif

6.775 CMOS Analog and Mixed-Signal Circuit Design
______

Graduate (Spring)
Prereq: 6.301
Units: 3-0-9
______
A detailed exposition of the principles involved in designing and optimizing analog and mixed-signal circuits in CMOS technologies. Small-signal and large-signal models. Systemic methodology for device sizing and biasing. Basic circuit building blocks. Operational amplifier design. Large signal considerations. Principles of switched capacitor networks including switched-capacitor and continuous-time integrated filters. Basic and advanced A/D and D/A converters, delta-sigma modulators, RF and other signal processing circuits. Design projects on op amps and subsystems are a required part of the subject. 4 Engineering Design Points.
H. S. Lee

6.776 High Speed Communication Circuits
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.301
Units: 3-3-6
______
Principles and techniques of high-speed integrated circuits used in wireless/wireline data links and remote sensing. On-chip passive component design of inductors, capacitors, and antennas. Analysis of distributed effects, such as transmission line modeling, S-parameters, and Smith chart. Transceiver architectures and circuit blocks, which include low-noise amplifiers, mixers, voltage-controlled oscillators, power amplifiers, and frequency dividers. Involves IC/EM simulation and laboratory projects.
R. Han

6.777[J] Design and Fabrication of Microelectromechanical Systems
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as2.372[J])
(Subject meets with2.374[J],6.717[J])
Prereq: 6.003 or 2.003, Physics II (GIR); or permission of instructor
Units: 3-0-9
______
Provides an introduction to microsystem design. Covers material properties, microfabrication technologies, structural behavior, sensing methods, electromechanical actuation, thermal actuation and control, multi-domain modeling, noise, and microsystem packaging. Applies microsystem modeling, and manufacturing principles to the design and analysis a variety of microscale sensors and actuators (e.g., optical MEMS, bioMEMS, and inertial sensors). Emphasizes modeling and simulation in the design process. Students taking the graduate version complete additional assignments. 4 Engineering Design Points.
Staff

6.780[J] Control of Manufacturing Processes
______

Graduate (Spring)
(Same subject as2.830[J])
Prereq: 2.008, 6.041B, 6.152, or 15.064
Units: 3-0-9
______
Statistical modeling and control in manufacturing processes. Use of experimental design and response surface modeling to understand manufacturing process physics. Defect and parametric yield modeling and optimization. Forms of process control, including statistical process control, run by run and adaptive control, and real-time feedback control. Application contexts include semiconductor manufacturing, conventional metal and polymer processing, and emerging micro-nano manufacturing processes.
D. E. Hardt, D. S. Boning

6.781[J] Nanostructure Fabrication
______

Graduate (Spring)
(Same subject as2.391[J])
Prereq: 6.152, 6.161, or 2.710; or permission of instructor
Units: 4-0-8
______
Describes current techniques used to analyze and fabricate nanometer-length-scale structures and devices. Emphasizes imaging and patterning of nanostructures, including fundamentals of optical, electron (scanning, transmission, and tunneling), and atomic-force microscopy; optical, electron, ion, and nanoimprint lithography, templated self-assembly, and resist technology. Surveys substrate characterization and preparation, facilities, and metrology requirements for nanolithography. Addresses nanodevice processing methods, such as liquid and plasma etching, lift-off, electroplating, and ion-implant. Discusses applications in nanoelectronics, nanomaterials, and nanophotonics.
K. K. Berggren


left arrow|6.00-6.299|6.30-6.799|6.80-6.ZZZ|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 6: Electrical Engineering and Computer Science
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Course 6: Electrical Engineering and Computer Science
Fall 2016


Computer Science

6.801 Machine Vision
______

Not offered academic year 2017-2018Undergrad (Fall)
(Subject meets with6.866)
Prereq: 6.003 or permission of instructor
Units: 3-0-9
Lecture: TR9.30-11 (32-124)
______
Deriving a symbolic description of the environment from an image. Understanding physics of image formation. Image analysis as an inversion problem. Binary image processing and filtering of images as preprocessing steps. Recovering shape, lightness, orientation, and motion. Using constraints to reduce the ambiguity. Photometric stereo and extended Gaussian sphere. Applications to robotics; intelligent interaction of machines with their environment. Students taking the graduate version complete different assignments.
B. K. P. Horn
Textbooks (Fall 2016)

6.802[J] Foundations of Computational and Systems Biology
______

Undergrad (Spring)
(Same subject as20.390[J])
(Subject meets with6.874[J],20.490,HST.506[J])
Prereq: Biology (GIR), 6.0002 or 6.01; 7.05; or permission of instructor
Units: 3-0-9
______
Provides an introduction to computational and systems biology. Includes units on the analysis of protein and nucleic acid sequences, protein structures, and biological networks. Presents principles and methods used for sequence alignment, motif finding, expression array analysis, structural modeling, structure design and prediction, and network analysis and modeling. Techniques include dynamic programming, Markov and hidden Markov models, Bayesian networks, clustering methods, and energy minimization approaches. Exposes students to emerging research areas. Designed for students with strong backgrounds in either molecular biology or computer science. Some foundational material covering basic programming skills, probability and statistics is provided for students with less quantitative backgrounds. Students taking graduate version complete additional assignments.
D. K. Gifford, T. S. Jaakkola

6.803 The Human Intelligence Enterprise
______

Undergrad (Spring)
(Subject meets with6.833)
Prereq: 6.034 or permission of instructor
Units: 3-0-9
______
Analyzes seminal work directed at the development of a computational understanding of human intelligence, such as work on learning, language, vision, event representation, commonsense reasoning, self reflection, story understanding, and analogy. Reviews visionary ideas of Turing, Minsky, and other influential thinkers. Examines the implications of work on brain scanning, developmental psychology, and cognitive psychology. Emphasis on discussion and analysis of original papers. Students taking graduate version complete additional assignments. Enrollment limited.
P. H. Winston

6.804[J] Computational Cognitive Science
______

Undergrad (Fall)
(Same subject as9.66[J])
(Subject meets with9.660)
Prereq: 6.008, 6.036, 6.041B, 9.40, 18.05, or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (46-3189)
______
Introduction to computational theories of human cognition. Focus on principles of inductive learning and inference, and the representation of knowledge. Computational frameworks covered include Bayesian and hierarchical Bayesian models; probabilistic graphical models; nonparametric statistical models and the Bayesian Occam's razor; sampling algorithms for approximate learning and inference; and probabilistic models defined over structured representations such as first-order logic, grammars, or relational schemas. Applications to understanding core aspects of cognition, such as concept learning and categorization, causal reasoning, theory formation, language acquisition, and social inference. Graduate students complete a final project.
J. Tenenbaum
No required or recommended textbooks

6.805[J] Foundations of Information Policy
______

Undergrad (Fall) HASS Social Sciences
(Same subject asSTS.085[J])
(Subject meets withSTS.487)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: R1-4 (66-168)
______
Studies the growth of computer and communications technology and the new legal and ethical challenges that reflect tensions between individual rights and societal needs. Topics include computer crime; intellectual property restrictions on software; encryption, privacy, and national security; academic freedom and free speech. Students meet and question technologists, activists, law enforcement agents, journalists, and legal experts. Instruction and practice in oral and written communication provided. Students taking graduate version complete additional assignments. Enrollment limited.
H. Abelson, M. Fischer, D. Weitzner
No required or recommended textbooks

6.806 Advanced Natural Language Processing
______

Undergrad (Fall)
(Subject meets with6.864)
Prereq: 6.046 or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (32-123)
______
Introduces the study of human language from a computational perspective, including syntactic, semantic and discourse processing models. Emphasizes machine learning methods and algorithms. Uses these methods and models in applications such as syntactic parsing, information extraction, statistical machine translation, dialogue systems, and summarization. Students taking graduate version complete additional assignments.
R. A. Barzilay
No textbook information available

6.807 Computational Fabrication
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 6.837 or permission of instructor
Units: 3-0-9
______
Introduces computational aspects of computer-aided design and manufacturing. Explores relevant methods in the context of additive manufacturing (e.g., 3D printing). Topics include computer graphics (geometry modeling, solid modeling, procedural modeling), physically-based simulation (kinematics, finite element method), 3D scanning/geometry processing, and an overview of 3D fabrication methods. Exposes students to the latest research in computational fabrication.
W. Matusik

6.809[J] Interactive Music Systems
(New)
______

Undergrad (Fall, Spring) HASS Arts
(Same subject as21M.385[J])
(Subject meets with21M.585)
Prereq: 21M.301, 6.01; or permission of instructor
Units: 3-0-9
Lecture: MW11-12.30 (24-033F)
______
Explores audio synthesis, musical structure, human computer interaction (HCI), and visual presentation for the creation of interactive musical experiences. Topics include audio synthesis; mixing and looping; MIDI sequencing; generative composition; motion sensors; music games; and graphics for UI, visualization, and aesthetics. Includes weekly programming assignments in python. Teams build an original, dynamic, and engaging interactive music system for their final project. Limited to 18.
E. Egozy, L. Kaelbling
Textbooks (Fall 2016)

6.811[J] Principles and Practice of Assistive Technology
______

Undergrad (Fall)
(Same subject as2.78[J],HST.420[J])
Prereq: Permission of instructor
Units: 2-4-6
Lecture: M2 (32-144) Lab: W2-5 (32-044)
______
Students work closely with people with disabilities to develop assistive and adaptive technologies that help them live more independently. Covers design methods and problem-solving strategies; human factors; human-machine interfaces; community perspectives; social and ethical aspects; and assistive technology for motor, cognitive, perceptual, and age-related impairments. Prior knowledge of one or more of the following areas useful: software; electronics; human-computer interaction; cognitive science; mechanical engineering; control; or MIT hobby shop, MIT PSC, or other relevant independent project experience.
R. C. Miller, J. E. Greenberg, J. J. Leonard
Textbooks (Fall 2016)

6.813 User Interface Design and Implementation
______

Undergrad (Spring)
(Subject meets with6.831)
Prereq: 6.005, 6.031, or permission of instructor
Units: 4-0-8
______
Examines human-computer interaction in the context of graphical user interfaces. Covers human capabilities, design principles, prototyping techniques, evaluation techniques, and the implementation of graphical user interfaces. Includes short programming assignments and a semester-long group project. Students taking the graduate version also have readings from current literature and additional assignments. Enrollment limited.
R. C. Miller

6.814 Database Systems
______

Undergrad (Fall)
(Subject meets with6.830)
Prereq: 6.033; 6.046 or 6.006; or permission of instructor
Units: 3-0-9
Lecture: MW2.30-4 (32-155)
______
Topics related to the engineering and design of database systems, including data models; database and schema design; schema normalization and integrity constraints; query processing; query optimization and cost estimation; transactions; recovery; concurrency control; isolation and consistency; distributed, parallel and heterogeneous databases; adaptive databases; trigger systems; pub-sub systems; semi structured data and XML querying. Lecture and readings from original research papers. Semester-long project and paper. Students taking graduate version complete different assignments. Enrollment may be limited.
S. R. Madden
No textbook information available

6.815 Digital and Computational Photography
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with6.865)
Prereq: Calculus II (GIR), 6.005 or 6.031
Units: 3-0-9
______
Presents fundamentals and applications of hardware and software techniques used in digital and computational photography, with an emphasis on software methods. Provides sufficient background to implement solutions to photographic challenges and opportunities. Topics include cameras and image formation, image processing and image representations, high-dynamic-range imaging, human visual perception and color, single view 3-D model reconstruction, morphing, data-rich photography, super-resolution, and image-based rendering. Students taking graduate version complete additional assignments.
F. P. Durand

6.816 Multicore Programming
______

Undergrad (Spring)
(Subject meets with6.836)
Prereq: 6.006
Units: 4-0-8
______
Introduces principles and core techniques for programming multicore machines. Topics include locking, scalability, concurrent data structures, multiprocessor scheduling, load balancing, and state-of-the-art synchronization techniques, such as transactional memory. Includes sequence of programming assignments on a large multicore machine, culminating with the design of a highly concurrent application. Students taking graduate version complete additional assignments.
N. Shavit

6.819 Advances in Computer Vision
______

Undergrad (Fall)
(Subject meets with6.869)
Prereq: 6.041B or 6.042; 18.06
Units: 3-0-9
Lecture: TR9.30-11 (34-101)
______
Advanced topics in computer vision with a focus on the use of machine learning techniques and applications in graphics and human-computer interface. Covers image representations, texture models, structure-from-motion algorithms, Bayesian techniques, object and scene recognition, tracking, shape modeling, and image databases. Applications may include face recognition, multimodal interaction, interactive systems, cinematic special effects, and photorealistic rendering. Covers topics complementary to 6.801. Students taking graduate version complete additional assignments.
W. T. Freeman, A. Torralba
No textbook information available

6.820 Foundations of Program Analysis
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.035
Units: 3-0-9
______
Presents major principles and techniques for program analysis. Includes formal semantics, type systems and type-based program analysis, abstract interpretation and model checking and synthesis. Emphasis on Haskell and Ocaml, but no prior experience in these languages is assumed. Student assignments include implementing of techniques covered in class, including building simple verifiers.
A. Solar-Lezama

6.823 Computer System Architecture
______

Graduate (Spring)
Prereq: 6.004
Units: 4-0-8
______
Introduction to the principles underlying modern computer architecture. Emphasizes the relationship among technology, hardware organization, and programming systems in the evolution of computer architecture. Topics include pipelined, out-of-order, and speculative execution; caches, virtual memory and exception handling, superscalar, very long instruction word (VLIW), vector, and multithreaded processors; on-chip networks, memory models, synchronization, and cache coherence protocols for multiprocessors.
Arvind, J. S. Emer, D. Sanchez

6.824 Distributed Computer Systems Engineering
______

Graduate (Spring)
Prereq: 6.033, permission of instructor
Units: 3-0-9
______
Abstractions and implementation techniques for engineering distributed systems: remote procedure call, threads and locking, client/server, peer-to-peer, consistency, fault tolerance, and security. Readings from current literature. Individual laboratory assignments culminate in the construction of a fault-tolerant and scalable network file system. Programming experience with C/C++ required. Enrollment limited.
R. T. Morris, M. F. Kaashoek

6.828 Operating System Engineering
______

Graduate (Fall)
Prereq: 6.005 or 6.031, 6.033
Units: 3-6-3
Lecture: MW1-2.30 (1-190) +final
______
Fundamental design and implementation issues in the engineering of operating systems. Lectures based on the study of a symmetric multiprocessor version of UNIX version 6 and research papers. Topics include virtual memory; file system; threads; context switches; kernels; interrupts; system calls; interprocess communication; coordination, and interaction between software and hardware. Individual laboratory assignments accumulate in the construction of a minimal operating system (for an x86-based personal computer) that implements the basic operating system abstractions and a shell. Knowledge of programming in the C language is a prerequisite.
M. F. Kaashoek
No textbook information available

6.829 Computer Networks
______

Graduate (Fall)
Prereq: 6.033 or permission of instructor
Units: 4-0-8
URL: http://mit.edu/6.829
Lecture: TR1-2.30 (32-144)
______
Topics on the engineering and analysis of network protocols and architecture, including architectural principles for designing heterogeneous networks; transport protocols; Internet routing; router design; congestion control and network resource management; wireless networks; network security; naming; overlay and peer-to-peer networks. Readings from original research papers. Semester-long project and paper.
H. Balakrishnan, D. Katabi
No textbook information available

6.830 Database Systems
______

Graduate (Fall)
(Subject meets with6.814)
Prereq: 6.033; 6.046 or 6.006; or permission of instructor
Units: 3-0-9
Lecture: MW2.30-4 (32-155)
______
Topics related to the engineering and design of database systems, including data models; database and schema design; schema normalization and integrity constraints; query processing; query optimization and cost estimation; transactions; recovery; concurrency control; isolation and consistency; distributed, parallel and heterogeneous databases; adaptive databases; trigger systems; pub-sub systems; semi structured data and XML querying. Lecture and readings from original research papers. Semester-long project and paper. Students taking graduate version complete different assignments. Enrollment may be limited.
S. R. Madden
Textbooks (Fall 2016)

6.831 User Interface Design and Implementation
______

Graduate (Spring)
(Subject meets with6.813)
Prereq: 6.005, 6.031, or permission of instructor
Units: 4-0-8
URL: http://groups.csail.mit.edu/uid/6.831/
______
Examines human-computer interaction in the context of graphical user interfaces. Covers human capabilities, design principles, prototyping techniques, evaluation techniques, and the implementation of graphical user interfaces. Includes short programming assignments and a semester-long group project. Students taking the graduate version also have readings from current literature and additional assignments. Enrollment limited.
R. C. Miller

6.832 Underactuated Robotics
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.141, 2.12, 2.165, or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Covers nonlinear dynamics and control of underactuated mechanical systems, with an emphasis on computational methods. Topics include nonlinear dynamics of passive robots (walkers, swimmers, flyers), motion planning, robust and optimal control, reinforcement learning/approximate optimal control, and the influence of mechanical design on control. Includes examples from biology and applications to legged locomotion, compliant manipulation, underwater robots, and flying machines.
R. Tedrake

6.833 The Human Intelligence Enterprise
______

Graduate (Spring)
(Subject meets with6.803)
Prereq: 6.034
Units: 3-0-9
______
Analyzes seminal work directed at the development of a computational understanding of human intelligence, such as work on learning, language, vision, event representation, commonsense reasoning, self reflection, story understanding, and analogy. Reviews visionary ideas of Turing, Minsky, and other influential thinkers. Examines the implications of work on brain scanning, developmental psychology, and cognitive psychology. Emphasis on discussion and analysis of original papers. Requires the completion of additional exercises and a substantial term project. Enrollment limited.
P. H. Winston

6.834[J] Cognitive Robotics
______

Graduate (Spring)
(Same subject as16.412[J])
Prereq: 6.041B, 6.042, or 16.09; 16.413 or 6.034
Units: 3-0-9
______
Algorithms and paradigms for creating a wide range of robotic systems that act intelligently and robustly, by reasoning extensively from models of themselves and their world. Examples range from autonomous Mars explorers and cooperative air vehicles, to everyday embedded devices. Topics include deduction and search in real-time; temporal, decision-theoretic and contingency planning; dynamic execution and re-planning; reasoning about hidden state and failures; reasoning under uncertainty, path planning, mapping and localization, and cooperative and distributed robotics.
B. C. Williams

6.835 Intelligent Multimodal User Interfaces
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 6.005, 6.031, 6.034, or permission of instructor
Units: 3-0-9
______
Implementation and evaluation of intelligent multi-modal user interfaces, taught from a combination of hands-on exercises and papers from the original literature. Topics include basic technologies for handling speech, vision, pen-based interaction, and other modalities, as well as various techniques for combining modalities. Substantial readings and a term project, where students build an interface to illustrate one or more themes of the course.
R. Davis

6.836 Multicore Programming
______

Graduate (Spring)
(Subject meets with6.816)
Prereq: 6.006
Units: 4-0-8
URL: http://web.mit.edu/6.836
______
Introduces principles and core techniques for programming multicore machines. Topics include locking, scalability, concurrent data structures, multiprocessor scheduling, load balancing, and state-of-the-art synchronization techniques, such as transactional memory. Includes sequence of programming assignments on a large multicore machine, culminating with the design of a highly concurrent application. Students taking graduate version complete additional assignments.
N. Shavit

6.837 Computer Graphics
______

Undergrad (Fall)
Prereq: Calculus II (GIR), 6.005 or 6.031; or permission of instructor
Units: 3-0-9
Lecture: TR2.30-4 (4-370)
______
Introduction to computer graphics algorithms, software and hardware. Topics include ray tracing, the graphics pipeline, transformations, texture mapping, shadows, sampling, global illumination, splines, animation and color.
F. P. Durand, W. Matusik
No textbook information available

6.838 Advanced Topics in Computer Graphics
______

Graduate (Spring) Can be repeated for credit
Prereq: 6.837
Units: 3-0-9
URL: https://ocw-int.mit.edu/6/6.838/f02/index.html
______
In-depth study of an active research topic in computer graphics. Topics change each term. Readings from the literature, student presentations, short assignments, and a programming project.
W. Matusik

6.839 Advanced Computer Graphics
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.06, 6.005, 6.031, 6.837, or permission of instructor
Units: 3-0-9
______
A graduate level course investigates computational problems in rendering, animation, and geometric modeling. The course draws on advanced techniques from computational geometry, applied mathematics, statistics, scientific computing and other. Substantial programming experience required.
W. Matusik

6.840[J] Theory of Computation
______

Graduate (Fall)
(Same subject as18.4041[J])
(Subject meets with18.404)
Prereq: 18.200 or 18.062J
Units: 4-0-8
URL: http://math.mit.edu/classes/18.404
1st mtg Sept 8 at 2.30. Room 54-100. Lecture: TR2.30-4 (2-190) Recitation: F12 (2-143) or F1 (2-139) or F2 (2-139) +final
______
A more extensive and theoretical treatment of the material in 6.045J/18.400J, emphasizing computability and computational complexity theory. Regular and context-free languages. Decidable and undecidable problems, reducibility, recursive function theory. Time and space measures on computation, completeness, hierarchy theorems, inherently complex problems, oracles, probabilistic computation, and interactive proof systems. Students in Course 18 must register for the undergraduate version, 18.404.
M. Sipser
Textbooks (Fall 2016)

6.841[J] Advanced Complexity Theory
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as18.405[J])
Prereq: 18.404
Units: 3-0-9
______
Current research topics in computational complexity theory. Nondeterministic, alternating, probabilistic, and parallel computation models. Boolean circuits. Complexity classes and complete sets. The polynomial-time hierarchy. Interactive proof systems. Relativization. Definitions of randomness. Pseudo-randomness and derandomizations. Interactive proof systems and probabilistically checkable proofs.
D. Moshkovitz

6.842 Randomness and Computation
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.046, 6.840
Units: 3-0-9
______
The power and sources of randomness in computation. Connections and applications to computational complexity, computational learning theory, cryptography and combinatorics. Topics include: probabilistic proofs, uniform generation and approximate counting, Fourier analysis of Boolean functions, computational learning theory, expander graphs, pseudorandom generators, derandomization.
R. Rubinfeld

6.845 Quantum Complexity Theory
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.045, 6.840, 18.435
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduction to quantum computational complexity theory, the study of the fundamental capabilities and limitations of quantum computers. Topics include complexity classes, lower bounds, communication complexity, proofs and advice, and interactive proof systems in the quantum world; classical simulation of quantum circuits. The objective is to bring students to the research frontier.
S. Aaronson

6.846 Parallel Computing
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: 6.004 or permission of instructor
Units: 3-0-9
______
Introduction to parallel and multicore computer architecture and programming. Topics include the design and implementation of multicore processors; networking, video, continuum, particle and graph applications for multicores; communication and synchronization algorithms and mechanisms; locality in parallel computations; computational models, including shared memory, streams, message passing, and data parallel; multicore mechanisms for synchronization, cache coherence, and multithreading. Performance evaluation of multicores; compilation and runtime systems for parallel computing. Substantial project required.
A. Agarwal

6.849 Geometric Folding Algorithms: Linkages, Origami, Polyhedra
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 6.046 or permission of instructor
Units: 3-0-9
URL: http://courses.csail.mit.edu/6.849/
______
Covers discrete geometry and algorithms underlying the reconfiguration of foldable structures, with applications to robotics, manufacturing, and biology. Linkages made from one-dimensional rods connected by hinges: constructing polynomial curves, characterizing rigidity, characterizing unfoldable versus locked, protein folding. Folding two-dimensional paper (origami): characterizing flat foldability, algorithmic origami design, one-cut magic trick. Unfolding and folding three-dimensional polyhedra: edge unfolding, vertex unfolding, gluings, Alexandrov's Theorem, hinged dissections.
E. D. Demaine

6.850 Geometric Computing
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 6.046
Units: 3-0-9
______
Introduction to the design and analysis of algorithms for geometric problems, in low- and high-dimensional spaces. Algorithms: convex hulls, polygon triangulation, Delaunay triangulation, motion planning, pattern matching. Geometric data structures: point location, Voronoi diagrams, Binary Space Partitions. Geometric problems in higher dimensions: linear programming, closest pair problems. High-dimensional nearest neighbor search and low-distortion embeddings between metric spaces. Geometric algorithms for massive data sets: external memory and streaming algorithms. Geometric optimization.
P. Indyk

6.851 Advanced Data Structures
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.046
Units: 3-0-9
URL: http://courses.csail.mit.edu/6.851/
______
More advanced and powerful data structures for answering several queries on the same data. Such structures are crucial in particular for designing efficient algorithms. Dictionaries; hashing; search trees. Self-adjusting data structures; linear search; splay trees; dynamic optimality. Integer data structures; word RAM. Predecessor problem; van Emde Boas priority queues; y-fast trees; fusion trees. Lower bounds; cell-probe model; round elimination. Dynamic graphs; link-cut trees; dynamic connectivity. Strings; text indexing; suffix arrays; suffix trees. Static data structures; compact arrays; rank and select. Succinct data structures; tree encodings; implicit data structures. External-memory and cache-oblivious data structures; B-trees; buffer trees; tree layout; ordered-file maintenance. Temporal data structures; persistence; retroactivity.
E. D. Demaine

6.852[J] Distributed Algorithms
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as18.437[J])
Prereq: 6.046
Units: 3-0-9
URL: http://theory.csail.mit.edu/classes/6.852/
Subject Cancelled Subject Cancelled
______
Design and analysis of concurrent algorithms, emphasizing those suitable for use in distributed networks. Process synchronization, allocation of computational resources, distributed consensus, distributed graph algorithms, election of a leader in a network, distributed termination, deadlock detection, concurrency control, communication, and clock synchronization. Special consideration given to issues of efficiency and fault tolerance. Formal models and proof methods for distributed computation.
N. A. Lynch

6.853 Topics in Algorithmic Game Theory
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 6.006 or 6.046
Units: 3-0-9
URL: http://people.csail.mit.edu/costis/6896sp10/
______
Presents research topics at the interface of computer science and game theory, with an emphasis on algorithms and computational complexity. Explores the types of game-theoretic tools that are applicable to computer systems, the loss in system performance due to the conflicts of interest of users and administrators, and the design of systems whose performance is robust with respect to conflicts of interest inside the system. Algorithmic focus is on algorithms for equilibria, the complexity of equilibria and fixed points, algorithmic tools in mechanism design, learning in games, and the price of anarchy.
K. Daskalakis

6.854[J] Advanced Algorithms
______

Graduate (Fall)
(Same subject as18.415[J])
Prereq: 6.041B, 6.042, or 18.600; 6.046
Units: 5-0-7
URL: http://theory.lcs.mit.edu/classes/6.854/
Lecture: MWF2.30-4 (32-141)
______
First-year graduate subject in algorithms. Emphasizes fundamental algorithms and advanced methods of algorithmic design, analysis, and implementation. Surveys a variety of computational models and the algorithms for them. Data structures, network flows, linear programming, computational geometry, approximation algorithms, online algorithms, parallel algorithms, external memory, streaming algorithms.
A. Moitra, D. R. Karger
No required or recommended textbooks

6.856[J] Randomized Algorithms
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as18.416[J])
Prereq: 6.854J, 6.041B or 6.042J
Units: 5-0-7
______
Studies how randomization can be used to make algorithms simpler and more efficient via random sampling, random selection of witnesses, symmetry breaking, and Markov chains. Models of randomized computation. Data structures: hash tables, and skip lists. Graph algorithms: minimum spanning trees, shortest paths, and minimum cuts. Geometric algorithms: convex hulls, linear programming in fixed or arbitrary dimension. Approximate counting; parallel algorithms; online algorithms; derandomization techniques; and tools for probabilistic analysis of algorithms.
D. R. Karger

6.857 Network and Computer Security
______

Graduate (Spring)
Prereq: 6.033, 6.042J
Units: 4-0-8
URL: http://web.mit.edu/6.857/www/
______
Emphasis on applied cryptography and may include: basic notion of systems security, crypotographic hash functions, symmetric crypotography (one-time pad, stream ciphers, block ciphers), cryptanalysis, secret-sharing, authentication codes, public-key cryptography (encryption, digital signatures), public-key attacks, web browser security, biometrics, electronic cash, viruses, electronic voting, Assignments include a group final project. Topics may vary year to year.
R. L. Rivest

6.858 Computer Systems Security
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.033, 6.005 or 6.031
Units: 3-6-3
URL: http://css.csail.mit.edu/6.858/
Subject Cancelled Subject Cancelled
______
Design and implementation of secure computer systems. Lectures cover attacks that compromise security as well as techniques for achieving security, based on recent research papers. Topics include operating system security, privilege separation, capabilities, language-based security, cryptographic network protocols, trusted hardware, and security in web applications and mobile phones. Labs involve implementing and compromising a web application that sandboxes arbitrary code, and a group final project.
N. B. Zeldovich

6.859[J] Integer Programming and Combinatorial Optimization
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as15.083[J])
Prereq: 15.081J or permission of instructor
Units: 4-0-8
______
In-depth treatment of the modern theory of integer programming and combinatorial optimization, emphasizing geometry, duality, and algorithms. Topics include formulating problems in integer variables, enhancement of formulations, ideal formulations, integer programming duality, linear and semidefinite relaxations, lattices and their applications, the geometry of integer programming, primal methods, cutting plane methods, connections with algebraic geometry, computational complexity, approximation algorithms, heuristic and enumerative algorithms, mixed integer programming and solutions of large-scale problems.
D. J. Bertsimas, A. S. Schulz

6.860[J] Statistical Learning Theory and Applications
(New)
______

Graduate (Fall)
(Same subject as9.520[J])
Prereq: 6.867, 6.041B, 18.06, or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (46-3310)
______
Provides students with the knowledge needed to use and develop advanced machine learning solutions to challenging problems. Covers foundations and recent advances of machine learning in the framework of statistical learning theory. Focuses on regularization techniques key to high-dimensional supervised learning. Starting from classical methods such as regularization networks and support vector machines, addresses state-of-the-art techniques based on principles such as geometry or sparsity, and discusses a variety of algorithms for supervised learning, feature selection, structured prediction, and multitask learning. Also focuses on unsupervised learning of data representations, with an emphasis on hierarchical (deep) architectures.
T. Poggio, L. Rosasco
No required or recommended textbooks

6.861[J] Aspects of a Computational Theory of Intelligence
(New)
______

Graduate (Fall)
(Same subject as9.523[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: F11-2 (46-3189)
______
Integrates neuroscience, cognitive and computer science to explore the nature of intelligence, how it is produced by the brain, and how it can be replicated in machines. Discusses an array of current research connected through an overarching theme of how it contributes to a computational account of how humans analyze dynamic visual imagery to understand objects and actions in the world.
T. Poggio, S. Ullman
No required or recommended textbooks

6.862 Applied Machine Learning
(New)
______

Graduate (Spring)
(Subject meets with6.036)
Prereq: Permission of instructor
Units: 4-0-8
______
Introduces principles, algorithms, and applications of machine learning from the point of view of modeling and prediction; formulation of learning problems; representation, over-fitting, generalization; clustering, classification, probabilistic modeling; and methods such as support vector machines, hidden Markov models, and Bayesian networks. Students taking graduate version complete different assignments.
R. Barzilay, T. Jaakkola

6.863[J] Natural Language and the Computer Representation of Knowledge
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as9.611[J])
Prereq: 6.034
Units: 3-3-6
______
Explores the relationship between computer representation of knowledge and the structure of natural language. Emphasizes development of analytical skills necessary to judge the computational implications of grammatical formalisms, and uses concrete examples to illustrate particular computational issues. Efficient parsing algorithms for context-free grammars; Treebank grammars and statistical parsing. Question answering systems. Extensive laboratory work on building natural language processing systems. 8 Engineering Design Points.
R. C. Berwick

6.864 Advanced Natural Language Processing
______

Graduate (Fall)
(Subject meets with6.806)
Prereq: 6.046 or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (32-123)
______
Introduces the study of human language from a computational perspective, including syntactic, semantic and discourse processing models. Emphasizes machine learning methods and algorithms. Uses these methods and models in applications such as syntactic parsing, information extraction, statistical machine translation, dialogue systems, and summarization. Students taking graduate version complete additional assignments.
R. A. Barzilay
No textbook information available

6.865 Advanced Computational Photography
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with6.815)
Prereq: Calculus II (GIR), 6.005 or 6.031
Units: 3-0-9
______
Presents fundamentals and applications of hardware and software techniques used in digital and computational photography, with an emphasis on software methods. Provides sufficient background to implement solutions to photographic challenges and opportunities. Topics include cameras and image formation, image processing and image representations, high-dynamic-range imaging, human visual perception and color, single view 3-D model reconstruction, morphing, data-rich photography, super-resolution, and image-based rendering. Students taking graduate version complete additional assignments.
F. P. Durand

6.866 Machine Vision
______

Not offered academic year 2017-2018Graduate (Fall)
(Subject meets with6.801)
Prereq: 6.003 or permission of instructor
Units: 3-0-9
Lecture: TR9.30-11 (32-124)
______
Intensive introduction to the process of generating a symbolic description of the environment from an image. Students expected to attend the 6.801 lectures as well as occasional seminar meetings on special topics. Material presented in 6.801 is supplemented by reading from the literature. Students required to implement a project on a topic of their choice from the material covered.
B. K. P. Horn
Textbooks (Fall 2016)

6.867 Machine Learning
______

Graduate (Fall)
Prereq: 6.041B or 18.600, 18.06
Units: 3-0-9
Lecture: TR9.30-11 (26-100) Recitation: F9 (26-322) or F10 (26-322) or F11 (26-322) or F12 (26-322) or F1 (26-322) or F2 (26-322) or F3 (26-322) or F4 (26-322) or F9 (36-144) or F10 (36-144) or F11 (36-144) or F12 (56-154) or F1 (56-154) or F2 (56-154) or F3 (56-154) or F4 (56-154)
______
Principles, techniques, and algorithms in machine learning from the point of view of statistical inference; representation, generalization, and model selection; and methods such as linear/additive models, active learning, boosting, support vector machines, non-parametric Bayesian methods, hidden Markov models, and Bayesian networks. Recommended prerequisite: 6.036.
T. Jaakkola, L. P. Kaelbling
Textbooks (Fall 2016)

6.868[J] The Society of Mind
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject asMAS.731[J])
Prereq: Must have read "The Society of Mind" and "The Emotion Machine"; permission of instructor
Units: 2-0-10
URL: http://web.media.mit.edu/~dustin/6.868/
______
Introduction to a theory that tries to explain how minds are made from collections of simpler processes. Treats such aspects of thinking as vision, language, learning, reasoning, memory, consciousness, ideals, emotions, and personality. Incorporates ideas from psychology, artificial intelligence, and computer science to resolve theoretical issues such as wholes vs. parts, structural vs. functional descriptions, declarative vs. procedural representations, symbolic vs. connectionist models, and logical vs. common-sense theories of learning. Enrollment limited.
M. Minsky

6.869 Advances in Computer Vision
______

Graduate (Fall)
(Subject meets with6.819)
Prereq: 6.041B or 6.042; 18.06
Units: 3-0-9
Lecture: TR9.30-11 (34-101)
______
Advanced topics in computer vision with a focus on the use of machine learning techniques and applications in graphics and human-computer interface. Covers image representations, texture models, structure-from-motion algorithms, Bayesian techniques, object and scene recognition, tracking, shape modeling, and image databases. Applications may include face recognition, multimodal interaction, interactive systems, cinematic special effects, and photorealistic rendering. Covers topics complementary to 6.866. Students taking graduate version complete additional assignments.
W. T. Freeman, A. Torralba
No textbook information available

6.870 Advanced Topics in Computer Vision
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: 6.801, 6.869, or permission of instructor
Units: 3-0-9
______
Seminar exploring advanced research topics in the field of computer vision; focus varies with lecturer. Typically structured around discussion of assigned research papers and presentations by students. Example research areas explored in this seminar include learning in vision, computational imaging techniques, multimodal human-computer interaction, biomedical imaging, representation and estimation methods used in modern computer vision.
W. T. Freeman, B. K. P. Horn, A. Torralba

6.871 Performance Engineering of Software Systems
______

Graduate (Fall)
(Subject meets with6.172)
Prereq: 6.004, 6.006, 6.005 or 6.031
Units: 3-12-3
URL: http://www.ai.mit.edu/courses/6.871/
Lecture: TR2.30-4 (34-101) Lab: F10-12 (4-265) or F1-3 (4-265) or F3-5 (4-265) or F10-12 (24-307) or F1-3 (34-301) or F3-5 (34-301) or F2-4 (34-304) or F3-5 (36-155)
______
Project-based introduction to building efficient, high-performance and scalable software systems. Topics include performance analysis, algorithmic techniques for high performance, instruction-level optimizations, vectorization, cache and memory hierarchy optimization, and parallel programming. Students taking graduate version complete additional assignments.
S. Amarasinghe, C. E. Leiserson
No textbook information available

6.872[J] Biomedical Computing
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject asHST.950[J])
Prereq: 6.034, 6.036, or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Analyzes computational needs of clinical medicine, reviews systems and approaches that have been used to support those needs, and the relationship between clinical data and gene and protein measurements to support precision medicine. Topics include the nature of clinical data, architecture and design of healthcare information systems, privacy and security issues, medical expert systems, predictive models and machine learning from big data in healthcare, and an introduction to bioinformatics. Case studies and guest lectures describe contemporary institutions, systems, and research projects. Term project using large clinical and genomic data sets integrates classroom topics.
G. Alterovitz, P. Szolovits

6.874[J] Computational Systems Biology
______

Graduate (Spring)
(Same subject asHST.506[J])
(Subject meets with6.802[J],20.390[J],20.490)
Prereq: Biology (GIR); 18.600 or 6.041B
Units: 3-0-9
______
Presents advanced machine learning and algorithmic approaches for contemporary problems in biology drawing upon recent advances in the literature. Topics include biological discovery in heterogeneous cellular populations; single cell data analysis; regulatory factor binding; motif discovery; gene expression analysis; regulatory networks (discovery, validation, data integration, protein-protein interactions, signaling, chromatin accessibility analysis); predicting phenotype from genotype; and experimental design (model validation, interpretation of interventions). Computational methods presented include deep learning, dimensionality reduction, clustering, directed and undirected graphical models, significance testing, Dirichlet processes, and topic models. Multidisciplinary team-oriented final research project.
D. K. Gifford

6.875[J] Cryptography and Cryptanalysis
______

Graduate (Spring)
(Same subject as18.425[J])
Prereq: 6.046J
Units: 3-0-9
______
A rigorous introduction to modern cryptography. Emphasis on the fundamental cryptographic primitives of public-key encryption, digital signatures, pseudo-random number generation, and basic protocols and their computational complexity requirements.
S. Goldwasser, S. Micali

6.876 Advanced Topics in Cryptography
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: 6.875
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Recent results in cryptography, interactive proofs, and cryptographic game theory.
S. Goldwasser, S. Micali

6.878[J] Advanced Computational Biology: Genomes, Networks, Evolution
______

Graduate (Fall)
(Same subject asHST.507[J])
(Subject meets with6.047)
Prereq: 6.006, 6.041B, Biology (GIR); or permission of instructor
Units: 4-0-8
Lecture: TR1-2.30 (32-141) Recitation: F3 (4-237)
______
See description for 6.047. Additionally examines recent publications in the areas covered, with research-style assignments. A more substantial final project is expected, which can lead to a thesis and publication.
M. Kellis
No textbook information available

6.881, 6.882 Advanced Topics in Artificial Intelligence
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______

6.883 Advanced Topics in Artificial Intelligence
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______

6.884 Advanced Topics in Artificial Intelligence
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Advanced study of topics in artificial intelligence. Specific focus varies from year to year. Consult department for details.
Consult Department

6.885-6.888 Advanced Topics in Computer Systems
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Advanced study of topics in computer systems. Specific focus varies from year to year. Consult department for details.
Consult Department

6.889-6.893 Advanced Topics in Theoretical Computer Science
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
6.889: URL: http://www.eecs.mit.edu/academics-admissions/academic-information/subject-updates-ft-2016
6.889: Lecture: TR1-2.30 (1-190)
______
Advanced study of topics in theoretical computer science. Specific focus varies from year to year. Consult department for details.
Consult Department
6.889: No textbook information available

6.894-6.896 Advanced Topics in Graphics and Human-Computer Interfaces
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Advanced study of topics in graphics and human-computer interfaces. Specific focus varies from year to year. Consult department for details.
Consult Department

6.901[J] Innovation Engineering: Moving Ideas to Impact
(New)
______

Undergrad (Fall)
(Same subject as15.359[J])
Prereq: None
Units: 3-3-6
URL: http://www.mit.edu:8001/courses/6.901/patent.html
Lecture: TR9-10.30 (1-390)
______
Designed for students to gain the perspective of a Chief Technology Officer of a start-up, large corporation, or a not-for-profit. Details the innovation process, from an idea's inception through impact in the economy, regardless of organizational setting. Explores how solutions are developed to become ready for broader market deployment. Includes testing and development of the problem-solution fit, probing of solutions for robustness, and testing of both technical and operational scaling of proposed solutions. Examines the human aspects of innovation, specifically issues of team building and readiness. Considers the broader system for innovation, including the role of key stakeholders in shaping its success in order to arrive at an impactful solution. Addresses intellectual property, the effect of regulations and social and cultural differences across varied global markets, and the personal skillset necessary to align and manage these issues.
V. Bulovic, F. Murray
No textbook information available

6.902 Engineering Innovation and Design
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:2.723,6.902,16.662)
Prereq: None
Units: 3-0-3
Lecture: M EVE (7-9 PM) (32-155) Recitation: M EVE (9 PM) (32-155) or W EVE (7 PM) (2-105) or W EVE (8 PM) (2-105)
______
Project-based seminar in innovative design thinking develops students' ability to conceive, implement, and evaluate successful projects in any engineering discipline. Lectures focus on the iterative design process and techniques to enhance creative analysis. Students use this process to design and implement robust voice recognition applications using a simple web-based system. They also give presentations and receive feedback to sharpen their communication skills for high emotional and intellectual impact. Guest lectures illustrate multidisciplinary approaches to design thinking.
B. Kotelly
No textbook information available

6.903 Patents, Copyrights, and the Law of Intellectual Property
______

Undergrad (Spring)
Prereq: None
Units: 3-0-6
______
Intensive introduction to the US law of intellectual property with major emphasis on patents, including the process of patent application and the remedies for patent infringement. Also focuses on copyrights and provides a brief look at trademarks and trade secrets. Presents comparisons of what can and cannot be protected, and what rights the owner does and does not obtain. Highlights issues relating to information technology, biogenetic materials, and business methods. Readings include judicial opinions and statutory material. No listeners.
S. M. Bauer

6.904 Ethics for Engineers
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.082,2.900,6.904,10.01,22.014)
Prereq: None
Units: 2-0-4
Lecture: M3-5 (66-144, 36-153) or T3-5 (37-212) or T EVE (7.30-9.30 PM) (66-144) or W3-5 (36-153)
______
Integrates classical readings that provide an overview of ethics with a survey of case studies that focus on ethical problems arising in the practice of engineering. Readings taken from a variety of sources, such as Aristotle, Machiavelli, Bacon, Hobbes, Locke, the Founding Fathers, and the Bible. Case studies include written analyses and films that address engineering disasters, biotechnology, court cases, ethical codes, and the ultimate scope and aims of engineering.
D. Doneson, B. L. Trout
No textbook information available

6.905 Large-scale Symbolic Systems
______

Undergrad (Spring)
(Subject meets with6.945)
Prereq: 6.034 or permission of instructor
Units: 3-0-9
______
Concepts and techniques for the design and implementation of large software systems that can be adapted to uses not anticipated by the designer. Applications include compilers, computer-algebra systems, deductive systems, and some artificial intelligence applications. Covers means for decoupling goals from strategy, mechanisms for implementing additive data-directed invocation, work with partially-specified entities, and how to manage multiple viewpoints. Topics include combinators, generic operations, pattern matching, pattern-directed invocation, rule systems, backtracking, dependencies, indeterminacy, memoization, constraint propagation, and incremental refinement. Students taking graduate version complete additional assignments.
G. J. Sussman

6.906 StartMIT: Workshop for Entrepreneurs and Innovators
______

Undergrad (IAP)
(Subject meets with6.936)
Prereq: None
Units: 4-0-2 [P/D/F]
______
Designed for students who are interested in entrepreneurship and want to explore the potential commercialization of their research project. Introduces practices for building a successful company, such as idea creation and validation, defining a value proposition, building a team, marketing, customer traction, and possible funding models. Students taking graduate version complete different assignments.
A. Chandrakasan

6.910 Independent Study in Electrical Engineering and Computer Science
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Consult department TBA.
______
Opportunity for independent study at the undergraduate level under regular supervision by a faculty member. Projects require prior approval.
Consult Department Undergraduate Office
No textbook information available

6.911 Engineering Leadership Lab
(ESD.05)
______

Undergrad (Fall, Spring) Can be repeated for credit
Engineering School-Wide Elective Subject.
(Offered under:6.911,16.650)
(Subject meets with6.913[J],16.667[J])
Prereq: None.Coreq: 6.912 or permission of instructor
Units: 0-2-1
Lab: F9-11 (32-124) or F1-3 (32-124) or F3-5 (32-124)
______
Exposes students to engineering frameworks, models, and cases in an interactive, experience-based environment, and hones leadership skills. Students participate in guided reflection on successes and discover opportunities for improvement in a controlled setting. Activities include design-implement activities, role-playing, simulations, case study analysis, and performance assessment by and of other students. Content throughout the term is frequently student-driven. First-year GEL Program students register for 6.911. Second-year GEL Program students register for 6.913. Preference to first-year students in the Bernard M. Gordon-MIT Engineering Leadership Program.
L. McGonagle, J. Feiler
No required or recommended textbooks

6.912 Engineering Leadership
(ESD.054)
______

Undergrad (Fall, Spring) Can be repeated for credit
Engineering School-Wide Elective Subject.
(Offered under:6.912,16.651)
Prereq: None.Coreq: 6.911 or permission of instructor
Units: 1-0-2
Lecture: M9-10.30 (5-233) or M11-12.30 (5-233) or T9-10.30 (5-233) or T11-12.30 (5-233)
______
Exposes students to the models and methods of engineering leadership within the contexts of conceiving, designing, implementing and operating products, processes and systems. Introduces models and theories, such as the Four Capabilities Framework and the Capabilities of Effective Engineering Leaders. Discusses the appropriate times and reasons to use particular models to deliver engineering success. Includes guest speakers and team projects that change from term to term. May be repeated for credit once with permission of instructor. Preference to first-year students in the Gordon Engineering Leadership Program.
J. Magarian, J. Schindall, L. McGonagle
No required or recommended textbooks

6.913 Engineering Leadership Lab
(ESD.050)
______

Undergrad (Fall, Spring) Can be repeated for credit
Engineering School-Wide Elective Subject.
(Offered under:6.913,16.667)
(Subject meets with6.911[J],16.650[J])
Prereq: 6.911
Units: 0-2-4
Lab: F9-11 (32-124) or F1-3 (32-124) or F3-5 (32-124)
______
Exposes students to engineering frameworks, models, and cases in an interactive, experience-based environment, and hones leadership skills. Students participate in guided reflection on successes and discover opportunities for improvement in a controlled setting. Activities include design-implement activities, role-playing, simulations, case study analysis, and performance assessment by and of other students. Content throughout the term is frequently student-driven. First year GEL Program students register for 6.911. Second year GEL Program students register for 6.913. Preference to second-year students in the Bernard M. Gordon-MIT Engineering Leadership Program.
L. McGonagle, J. Feiler
No required or recommended textbooks

6.914 Project Engineering
(ESD.052)
______

Undergrad (IAP)
Engineering School-Wide Elective Subject.
(Offered under:6.914,16.669)
Prereq: 6.911 or permission of instructor
Units: 1-2-1 [P/D/F]
Credit cannot also be received for1.040
______
Students attend a four-day off-site workshop where an introduction to basic principles, methods, and tools for project management in a realistic context are covered. In teams, students create a plan for a project of their choice; past projects include Debris Removal in Haiti and Food Preparation Robot for Restaurants. Develops skills applicable to the management of complex development projects. Topics include cost-benefit analysis, resource and cost estimation, and project control and delivery. Case studies highlight projects in both hardware/construction and software. Preference to students in the Bernard M. Gordon-MIT Engineering Leadership Program.
O. de Weck

6.915[J] Leading Creative and Innovative Teams
(New)
______

Undergrad (Spring)
(Same subject as16.671[J])
Prereq: None
Units: 6-0-6
______
Empowers future leaders in technology by developing a foundation of personal and team leadership skills. Grounded in research and theory, focuses on practical leadership skills and how they can be assessed, learned, and applied to group situations in technical and engineering contexts. Focuses on how to foster original and creative thinking in groups, and how groups can successfully move creative ideas toward implementation and value creation. Balances traditional learning methods and more experiential ones, such as role play simulations and project-based learning. Enrollment limited to seating capacity of classroom. Admittance may be controlled by lottery.
D. Nino, J. Schindall

6.920 Practical Work Experience
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units: 0-1-0 [P/D/F]
URL: http://www.eecs.mit.edu/ug/programs.html#6.910
Consult department TBA.
______
For Course 6 students participating in curriculum-related off-campus work experiences in electrical engineering or computer science. Before enrolling, students must have an employment offer from a company or organization and must find an EECS supervisor. Upon completion of the work the student must submit a letter from the employer evaluating the work accomplished, a substantive final report from the student, approved by the MIT supervisor. Subject to departmental approval. Consult Department Undergraduate Office for details on procedures and restrictions.
Consult Department Undergraduate Office
No textbook information available

6.921 6-A Internship
______

Undergrad (Summer)
Prereq: None
Units: 0-12-0 [P/D/F]
______
Provides academic credit for the first assignment of 6-A undergraduate students at companies affiliated with the department's 6-A internship program. Limited to students participating in the 6-A internship program.
T. Palacios
No textbook information available

6.922 Advanced 6-A Internship
______

Undergrad (Spring, Summer)
Prereq: 6.921
Units: 0-12-0 [P/D/F]
______
Provides academic credit for the second assignment of 6-A undergraduate students at companies affiliated with the department's 6-A internship program. Limited to students participating in the 6-A internship program.
T. Palacios
No textbook information available

6.928[J] Leading Creative Teams
(New)
______

Graduate (Fall, Spring)
(Same subject as16.990[J])
Prereq: None
Units: 3-1-5
Lecture: F9.30-12.30 (5-233) Lab: W3 (56-154) or F12.30 (5-233)
______
Prepares students to lead teams charged with developing creative solutions to challenging problems. Grounded in research but practical in focus, covers the development of basic leadership capabilities, such as motivating and influencing others, delegating, managing conflict, and communicating effectively; how to create, launch, develop, and adjourn teams; and how to foster creativity in small groups.
D. Nino, J. Schindall
No textbook information available

6.929[J] Energy Technology and Policy: From Principles to Practice
______

Graduate (Spring)
(Same subject as5.00[J],10.579[J],22.813[J])
Prereq: None
Units: 3-0-6
______
Develops analytical skills to lead a successful technology implementation with an integrated approach that combines technical, economical and social perspectives. Considers corporate and government viewpoints as well as international aspects, such as nuclear weapons proliferation and global climate issues. Discusses technologies such as oil and gas, nuclear, solar, and energy efficiency. Limited to 100.
J. Deutch

6.930 Management in Engineering
______

Undergrad (Fall)
Engineering School-Wide Elective Subject.
(Offered under:2.96,6.930,10.806,16.653)
Prereq: None
Units: 3-1-8
Lecture: MW11-12.30 (35-225) Lab: M4 (35-308) or T10 (1-273) or R4 (1-371) or F1 (1-132) or F2 (1-132)
______
Introduction and overview of engineering management. Financial principles, management of innovation, technical strategy and best management practices. Case study method of instruction emphasizes participation in class discussion. Focus is on the development of individual skills and management tools. Restricted to juniors and seniors.
H. S. Marcus, J.-H. Chun
No textbook information available

6.932[J] Linked Data Ventures
______

Graduate (Spring)
(Same subject as15.377[J])
Prereq: 6.005, 6.033, or permission of instructor
Units: 3-0-9
______
Provides practical experience in the use and development of semantic web technologies. Focuses on gaining practical insight from executives and practitioners who use these technologies in their companies. Working in multidisciplinary teams, students complete a term project to develop a sustainable prototype. Concludes with a professional presentation, judged by a panel of experts, and a technical presentation to faculty.
T. Berners-Lee, L. Kagal, K. Rae, R. Sturdevant

6.933 Entrepreneurship in Engineering: The Founder's Journey
______

Graduate (Fall, Spring)
Prereq: None
Units: 4-0-8
Lecture: TR EVE (7-9 PM) (32-141)
______
Immerses students in the experience of an engineer who founds a start-up company. Examines leadership, innovation, and creativity through the lens of an entrepreneur. Suitable for students interested in transforming an idea into a business or other realization for wide-scale societal impact. Covers critical aspects of validating ideas and assessing personal attributes needed to activate and lead a growing organization. Teams explore the basics of new venture creation and experimentation. Emphasizes personal skills and practical experiences. No listeners.
C. Chase
No textbook information available

6.935[J] Financial Market Dynamics and Human Behavior
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as15.481[J])
Prereq: 15.401, 15.414, or 15.415
Units: 4-0-5
______
Develops a new perspective on the dynamics of financial markets and the roles that human behavior and the business environment play in determining the evolution of behavior and institutions. Draws on a variety of disciplines to develop a more complete understanding of human behavior in the specific context of markets and other economic institutions. Incorporates practical applications from financial markets, the hedge fund industry, private equity, government regulation, and political economy. Students use ideas from this new perspective to formulate several new hypotheses regarding recent challenges to traditional economic thinking.
A. Lo

6.936 StartMIT: Workshop for Entrepreneurs and Innovators
______

Graduate (IAP)
(Subject meets with6.906)
Prereq: None
Units: 4-0-2 [P/D/F]
______
Designed for students who are interested in entrepreneurship and want to explore the potential commercialization of their research project. Introduces practices for building a successful company, such as idea creation and validation, defining a value proposition, building a team, marketing, customer traction, and possible funding models. Students taking graduate version complete different assignments.
A. Chandrakasan

6.941 Statistics for Research Projects: Statistical Modeling and Experiment Design
______

Graduate (IAP)
Not offered regularly; consult department
Prereq: None
Units: 2-2-2 [P/D/F]
______
Practical introduction to data analysis, statistical modeling, and experimental design, intended to provide essential skills for conducting research. Covers basic techniques such as hypothesis-testing and regression models for both traditional experiments and newer paradignms such as evaluating simulations. Assignments reinforce techniques through analyzing sample datasets and reading case studies. Students with research projects will be encouraged to share their experiences and project-specific questions.
Staff

6.945 Large-scale Symbolic Systems
______

Graduate (Spring)
(Subject meets with6.905)
Prereq: 6.034 or permission of instructor
Units: 3-0-9
______
Concepts and techniques for the design and implementation of large software systems that can be adapted to uses not anticipated by the designer. Applications include compilers, computer-algebra systems, deductive systems, and some artificial intelligence applications. Covers means for decoupling goals from strategy, mechanisms for implementing additive data-directed invocation, work with partially-specified entities, and how to manage multiple viewpoints. Topics include combinators, generic operations, pattern matching, pattern-directed invocation, rule systems, backtracking, dependencies, indeterminacy, memoization, constraint propagation, and incremental refinement. Students taking graduate version complete additional assignments.
G. J. Sussman

6.946[J] Classical Mechanics: A Computational Approach
______

Graduate (Fall)
(Same subject as8.351[J],12.620[J])
Prereq: Physics I (GIR), 18.03, permission of instructor
Units: 3-3-6
Credit cannot also be received for12.008
URL: http://swissnet.ai.mit.edu/~gjs/6946/index.html
Lecture: MWF11 (54-819) Lab: W EVE (7-10 PM) (14-0637)
______
Classical mechanics in a computational framework, Lagrangian formulation, action, variational principles, and Hamilton's principle. Conserved quantities, Hamiltonian formulation, surfaces of section, chaos, and Liouville's theorem. Poincaré integral invariants, Poincaré-Birkhoff and KAM theorems. Invariant curves and cantori. Nonlinear resonances, resonance overlap and transition to chaos. Symplectic integration. Adiabatic invariants. Applications to simple physical systems and solar system dynamics. Extensive use of computation to capture methods, for simulation, and for symbolic analysis. Programming experience required. Students taking the graduate version complete additional assignments.
J. Wisdom, G. J. Sussman
Textbooks (Fall 2016)

6.951 Graduate 6-A Internship
______

Graduate (Fall, Spring, Summer)
Prereq: 6.921 or 6.922
Units: 0-12-0 [P/D/F]
TBA.
______
Provides academic credit for a graduate assignment of graduate 6-A students at companies affiliated with the department's 6-A internship program. Limited to graduate students participating in the 6-A internship program.
T. Palacios
No textbook information available

6.952 Graduate 6-A Internship
______

Graduate (Fall, Spring, Summer)
Prereq: 6.951
Units: 0-12-0 [P/D/F]
TBA.
______
Provides academic credit for graduate students who require an additional term at the company to complete the graduate assignment of the department's 6-A internship program. This academic credit is for registration purposes only and cannot be used toward fulfilling the requirements of any degree program. Limited to graduate students participating in the 6-A internship program.
T. Palacios
No textbook information available

6.960 Introductory Research in Electrical Engineering and Computer Science
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Enrollment restricted to first-year graduate students in Electrical Engineering and Computer Science who are doing introductory research leading to an SM, EE, ECS, PhD, or ScD thesis. Opportunity to become involved in graduate research, under guidance of a staff member, on a problem of mutual interest to student and supervisor. Individual programs subject to approval of professor in charge.
L. A. Kolodziejski
No textbook information available

6.961 Introduction to Research in Electrical Engineering and Computer Science
______

Graduate (Fall, Spring, Summer)
Prereq: Permission of instructor
Units: 3-0-0
Lecture: M EVE (4-6 PM) (34-301)
______
Seminar on topics related to research leading to an SM, EE, ECS, PhD, or ScD thesis. Limited to first-year regular graduate students in EECS with a fellowship or teaching assistantship.
L. A. Kolodziejski
No textbook information available

6.962 Independent Study in Electrical Engineering and Computer Science
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Opportunity for independent study under regular supervision by a faculty member. Projects require prior approval.
L. A. Kolodziejksi
No textbook information available

6.980 Teaching Electrical Engineering and Computer Science
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
Consult department TBA.
______
For qualified students interested in gaining teaching experience. Classroom, tutorial, or laboratory teaching under the supervision of a faculty member. Enrollment limited by availability of suitable teaching assignments.
H. S. Lee, R. C. Miller
No required or recommended textbooks

6.981 Teaching Electrical Engineering and Computer Science
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
Consult department TBA.
______
For Teaching Assistants in Electrical Engineering and Computer Science, in cases where teaching assignment is approved for academic credit by the department.
H. S. Lee, R. C. Miller
No required or recommended textbooks

6.991 Research in Electrical Engineering and Computer Science
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
Consult department TBA.
______
For EECS MEng students who are Research Assistants in Electrical Engineering and Computer Science, in cases where the assigned research is approved for academic credit by the department. Hours arranged with research supervisor.
Consult Department Undergraduate Office
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

6.999 Practical Experience in EECS
______

Graduate (Fall, Spring)
Prereq: None
Units arranged [P/D/F]
Consult department TBA.
______
For Course 6 students in the SM/PhD track who seek practical off-campus research experiences or internships in electrical engineering or computer science. Before enrolling, students must have a firm employment offer from a company or organization and secure a research supervisor within EECS. Employers required to document the work accomplished. Research proposals subject to departmental approval; consult departmental Graduate Office.
L. A. Kolodziejski
No required or recommended textbooks

6.EPE UPOP Engineering Practice Experience
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.EPE,2.EPE,3.EPE,6.EPE,10.EPE,16.EPE,22.EPE)
Prereq: 2.EPW or permission of instructor
Units: 0-0-1 [P/D/F]
TBA.
______
Provides sophomores with guided practice in finding opportunities and excelling in the world of practice. Building on the skills and relationships acquired in the Engineering Practice Workshop, students receive coaching to articulate goals, invoke the UPOP network of mentors and employers, identify and pursue opportunities and negotiate terms of their summer assignment. Students complete a 10-12 week internship, which includes filing three progress reports, conducting one informational interview, and possibly hosting a site visit by MIT staff. Returning to campus as juniors, UPOP students take part in reflective exercises that aid assimilation of learning objectives and reinforce the cognitive link between all aspects of the UPOP experience and disciplinary fields of study. Sequence begins in the spring of sophomore year and ends in the fall of junior year.
Staff
No textbook information available

6.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No textbook information available

6.S897-6.S899 Special Subject in Computer Science
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
6.S897: Lecture: TR11-12.30 (56-191)
6.S898: Lecture: F10-1 (5-234)
6.S899: TBA.
______
Covers subject matter not offered in the regular curriculum. Consult department to learn of offerings for a particular term.
Consult Department
6.S897: No textbook information available
6.S898: No textbook information available
6.S899: No textbook information available

6.S911-6.S919 Special Subject in Electrical Engineering and Computer Science
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Covers subject matter not offered in the regular curriculum.
Consult Department

6.S963-6.S967 Special Studies: EECS
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
Subject Cancelled 6.S963 Cancelled
6.S964: TBA.
______
Opportunity for study of graduate-level topics related to electrical engineering and computer science but not included elsewhere in the curriculum. Registration under this subject normally used for situations involving small study groups. Normal registration is for 12 units. Registration subject to approval of professor in charge. Consult the department for details.
L. A. Kolodziejski
6.S963: No textbook information available
6.S964: No textbook information available

6.S974 Special Subject in Electrical Engineering and Computer Science
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______
Covers subject matter not offered in the regular curriculum. Consult department to learn of offerings for a particular term.
Consult Department

6.S975-6.S979 Special Subject in Electrical Engineering and Computer Science
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
6.S976: Lecture: W1-4 (E14-633) +final
______
Covers subject matter not offered in the regular curriculum. Consult department to learn of offerings for a particular term.
Consult Department
6.S976: No textbook information available

6.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Consult department TBA.
______
Program of research leading to the writing of an SM, EE, ECS, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member.
L. A. Kolodziejski
Textbooks arranged individually

6.THM Master of Engineering Program Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 6.UAT
Units arranged
Consult department TBA.
______
Program of research leading to the writing of an MEng thesis; to be arranged by the student and an appropriate MIT faculty member. Restricted to MEng students who have been admitted to the MEng program.
Consult Department Undergraduate Office
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

6.UR Undergraduate Research in Electrical Engineering and Computer Science
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
Consult department TBA.
______
Individual research project arranged with appropriate faculty member or approved supervisor. Forms and instructions for the proposal and final report are available in the EECS Undergraduate Office.
Consult Department Undergraduate Office
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


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Produced: 29-SEP-2016 06:37 AMFall 2016 Course 7: Biology
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Course 7: Biology
Fall 2016


Undergraduate Subjects


Introductory Biology

All five subjects cover the same core material, comprising about 50% of the course, while the remaining material is specialized for each version as described below. Core material includes fundamental principles of biochemistry, genetics, molecular biology, and cell biology. These topics address structure and regulation of genes, structure and synthesis of proteins, how these molecules are integrated into cells and how cells communicate with one another.

7.012 Introductory Biology
______

Undergrad (Fall) Biology
Prereq: None
Units: 5-0-7
Credit cannot also be received for7.013,7.014,7.015,7.016,ES.7012,ES.7013
URL: https://biology.mit.edu/course_listings_undergraduate/701x_introductory_biology
Recs begin Sept 12. Lecture: MWF10 (26-100) Recitation: MW12 (26-204) or MW1 (26-204) or MW12 (26-210) or MW1 (26-210) or MW12 (24-307) or MW1 (24-307) or TR9 (26-204) or TR10 (26-204) or TR9 (26-210) or TR10 (26-210) or TR11 (26-204) or TR12 (26-204) or TR11 (24-112) or TR12 (24-112) or TR11 (1-135) or TR12 (1-135, 26-210) or TR1 (26-210) or TR12 (26-310) or TR1 (26-310) or TR2 (26-210) or TR3 (26-210) or TBA +final
______
Exploration into areas of current research in molecular and cell biology, immunology, neurobiology, human genetics, biochemistry, and evolution. Enrollment limited to seating capacity of classroom. Admittance may be controlled by lottery.
E. Lander, R. Weinberg
Textbooks (Fall 2016)

7.013 Introductory Biology
______

Undergrad (Spring) Biology
Prereq: None
Units: 5-0-7
Credit cannot also be received for7.012,7.014,7.015,7.016,ES.7012,ES.7013
URL: https://biology.mit.edu/course_listings_undergraduate/701x_introductory_biology
______
Genomic approaches to human biology, including neuroscience, development, immunology, tissue repair and stem cells, tissue engineering, and infectious and inherited diseases, including cancer. Enrollment limited to seating capacity of classroom. Admittance may be controlled by lottery.
A. Amon, H. Sive

7.014 Introductory Biology
______

Undergrad (Spring) Biology
Units: 5-0-7
Credit cannot also be received for7.012,7.013,7.015,7.016,ES.7012,ES.7013
URL: https://biology.mit.edu/course_listings_undergraduate/701x_introductory_biology
______
Studies the fundamental principles of biology and their application towards understanding the Earth as a dynamical system shaped by life. Focuses on molecular ecology in order to show how processes at the molecular level can illuminate macroscopic properties, including evolution and maintenance of biogeochemical cycles, and ecological interactions in ecosystems ranging from the ocean to the human gut. Includes quantitative analysis of population growth, community structure, competition, mutualism and predation; highlights their role in shaping the biosphere. Enrollment limited to seating capacity of classroom. Admittance may be controlled by lottery.
G. C. Walker, S. W. Chisholm, M. Polz

7.015 Introductory Biology
______

Undergrad (Fall) Biology
Prereq: Advanced high school course covering cellular and molecular biology, or permission of instructor
Units: 5-0-7
Credit cannot also be received for7.012,7.013,7.014,7.016,ES.7012,ES.7013
Lecture: MWF10 Recitation: TR10 (26-302) or TR12 (26-322) +final
______
Emphasizes the application of fundamental biological principles to trending topics in microbiology and immunology. Specific modules focus on antibiotic resistance, influenza, genome-wide association studies, biotechnology (such as genetically modified organisms and personal genomics), the microbiome, and diabetes. Includes discussion of the social and ethical issues surrounding modern biology. Limited to 60; admittance may be controlled by lottery.
M. Laub, H. Ploegh
Textbooks (Fall 2016)

7.016 Introductory Biology
______

Undergrad (Fall) Biology
Prereq: None
Units: 5-0-7
Credit cannot also be received for7.012,7.013,7.014,7.015,ES.7012,ES.7013
Lecture: MWF10 (34-101) Recitation: MW12 (36-156) or MW1 (36-156, 26-322) or MW2 (26-322, 26-204) or MW3 (26-204) or TR9 (26-314) or TR10 (26-314, 24-307) or TR11 (24-307, 26-314) or TR12 (26-314, 26-302) or TR1 (26-302) +final
______
Introduction to fundamental principles of biochemistry, molecular biology and genetics for understanding the functions of living systems. Covers examples of the use of chemical biology and 21st-century molecular genetics in understanding human health and therapeutic intervention. Enrollment limited to seating capacity of classroom. Admittance may be controlled by lottery.
L. Boyer, B. Imperiali
Textbooks (Fall 2016)

7.02[J] Introduction to Experimental Biology and Communication
______

Undergrad (Fall, Spring) Institute Lab
(Same subject as10.702[J])
Prereq: Biology (GIR)
Units: 4-8-6
1st mtg 9/8 mandatory. Lecture: TR11 (32-155) Lab: TR1-5 (68-074) or WF1-5 (68-074) Recitation: M9-11 (68-121) or M1-3 (66-148, 4-146) or T9-11 (4-144) or W1-3 (68-121) or W9-11 (68-121) +final
______
Introduction to the experimental concepts and methods of molecular biology, biochemistry, and genetic analysis. Emphasis on experimental design, critical data analysis, and the development of written communications skills. 12 units may be applied to the General Institute Laboratory Requirement. Concurrent registration with 7.03 strongly recommended. Enrollment limited.
Fall:T. Baker, M. Gehring, K. D. Wittrup
Spring:T. Baker, O. Yilmaz, K. D. Wittrup
No required or recommended textbooks

7.03 Genetics
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Biology (GIR)
Units: 4-0-8
URL: https://biology.mit.edu/course_listings_undergraduate/703_genetics
Lecture: MWF11 (34-101) Recitation: M1 (26-310) or M2 (26-310) or M3 (36-155) or T10 (34-303) or T11 (34-303) or T2 (56-169) or M12 (56-191) or T12 (8-205) +final
______
The principles of genetics with application to the study of biological function at the level of molecules, cells, and multicellular organisms, including humans. Structure and function of genes, chromosomes, and genomes. Biological variation resulting from recombination, mutation, and selection. Population genetics. Use of genetic methods to analyze protein function, gene regulation, and inherited disease.
Fall:G. Fink, P. Gupta, P. Reddien
Spring:M. Hemann, A. Regev
Textbooks (Fall 2016)

7.05 General Biochemistry
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: 5.12, Biology (GIR), or permission of instructor
Units: 5-0-7
Credit cannot also be received for5.07,20.507
______
Contributions of biochemistry toward an understanding of the structure and functioning of organisms, tissues, and cells. Chemistry and functions of constituents of cells and tissues and the chemical and physical-chemical basis for the structures of nucleic acids, proteins, and carbohydrates. Basic enzymology and biochemical reaction mechanisms involved in macromolecular synthesis and degradation, signaling, transport, and movement. General metabolism of carbohydrates, fats, and nitrogen-containing materials such as amino acids, proteins, and related compounds.
M. Vander Heiden, M. Yaffe

7.06 Cell Biology
______

Undergrad (Fall, Spring)
Prereq: 7.03, 7.05
Units: 4-0-8
Lecture: MW9.30-11 (2-190) Recitation: F10 (26-204) or F11 (26-204) or F12 (26-204) or F1 (26-204) +final
______
Presents the biology of cells of higher organisms. Studies the structure, function, and biosynthesis of cellular membranes and organelles; cell growth and oncogenic transformation; transport, receptors, and cell signaling; the cytoskeleton, the extracellular matrix, and cell movements; cell division and cell cycle; functions of specialized cell types. Emphasizes the current molecular knowledge of cell biological processes as well as the genetic, biochemical, and other experimental approaches that resulted in these discoveries.
A. Martin, F. Solomon
Textbooks (Fall 2016)

7.08[J] Biological Chemistry II
______

Undergrad (Spring)
(Same subject as5.08[J])
(Subject meets with7.80)
Prereq: 5.12; 5.07 or 7.05
Units: 4-0-8
______
More advanced treatment of biochemical mechanisms that underlie biological processes. Topics include macromolecular machines such as the ribosome, the proteosome, fatty acid synthases as a paradigm for polyketide synthases and non-ribosomal polypeptide synthases, and polymerases. Emphasis is on experimental methods used to unravel these processes and how these processes fit into the cellular context and coordinate regulation.
E. Nolan

7.09 Quantitative and Computational Biology
______

Undergrad (Spring)
Prereq: 7.03, 7.05
Units: 3-0-9
______
Quantitative and computational analysis of biological systems at the molecular and cellular level. Includes models of biological processes across different time scales, from steady-state to kinetics of gene expression, circadian clock, cell growth, and evolutionary dynamics. Methods include physical, systems, and synthetic biology. Also covers second-generation sequencing technologies, and topics in computational analysis of genomes, including sequence alignment, motif finding, information theory and RNA secondary structure prediction.
C. Burge, G. W. Li

7.102 Laboratory in Molecular Biology
(New)
______

Undergrad (IAP) 1/2 Institute Lab
Prereq: None
Units: 0-5-1
______
Introduces basic methods of experimental molecular biology. Specific experiments vary from year-to-year, but will focus on the molecular genetic characterization of fundamental biological processes. Biology GIR or Chemistry GIR recommended. Limited to 30.
M. Sassanfar, D. Kim

7.11 Biology Teaching
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
For qualified undergraduate students interested in gaining some experience in teaching. Laboratory, tutorial, or classroom teaching under the supervision of a faculty member. Students selected by interview.
Consult Biology Education Office
No required or recommended textbooks

7.15 Experimental Molecular Genetics
______

Undergrad (Spring)
Prereq: 7.02, 7.03
Units: 4-16-10
______
In this project-based laboratory subject, students carry out independent molecular genetics experiments that develop skills in the planning, execution, and analysis of original experimental biological research. Specific research topic, which is determined by teaching staff, involves the application of modern biological methods, such as next-generation sequencing and metabolomics. Reading and writing assignments focus on the critical evaluation and discussion of relevant scientific literature. Emphasizes instruction in laboratory methods and the testing of hypotheses, as well as the critical analysis of experimental results.
J. Weng

7.18 Topics in Experimental Biology
______

Undergrad (Fall, Spring)
(Subject meets with7.19)
Prereq: 7.02, 7.03, 7.05
Units: 4-16-10
URL: https://biology.mit.edu/undergraduate/course_listings/project_labs/718_topics_experimental_biology
Lecture: TR2-4 (68-121) Lab: TBA
______
Independent experimental study under the direction of a member of the Biology Department faculty. Allows students with a strong interest in independent research to fulfill the project laboratory requirement for the Biology Department Program in the context of a research laboratory at MIT. The research must be conducted on the MIT campus and be a continuation of a previous 12-unit UROP project or full-time work over the summer. Written and oral presentation of the research results is required. Journal club discussions are used to help students evaluate and write scientific papers. Instruction and practice in written and oral communication is provided. Permission of the faculty research supervisor and the Biology Education Office must be obtained in advance.
Fall:D. Kim, A.J. Sinskey, C. Kaiser
Spring:D. Kim, C. Kaiser, U. Rajbhandary
No required or recommended textbooks

7.19 Communication in Experimental Biology
______

Undergrad (Fall, Spring)
(Subject meets with7.18)
Prereq: 7.02, 7.03, 7.05
Units: 4-4-4
URL: https://biology.mit.edu/undergraduate/course_listings/project_labs/718_topics_experimental_biology
Lecture: TR2-4 (68-121) Lab: TBA
______
Students carry out independent literature research. Meets with the seminar and writing tutorial portions of 7.18. Journal club discussions are used to help students evaluate and write scientific papers. Instruction and practice in written and oral communication is provided. Permission of the instructor and the Biology Education Office must be obtained in advance.
Fall:D. Kim, A.J. Sinskey, C. Kaiser
Spring:D. Kim, C. Kaiser, U. Rajbhandary
No required or recommended textbooks

7.20[J] Human Physiology
______

Undergrad (Fall)
(Same subject asHST.540[J])
Prereq: 7.05
Units: 5-0-7
Lecture: TR9-11 (E25-111) Recitation: T EVE (7.30 PM) (66-168) or W11 (66-168) +final
______
Comprehensive exploration of human physiology, emphasizing the molecular basis and applied aspects of organ function and regulation in health and disease. Includes a review of cell structure and function, as well as the mechanisms by which the endocrine and nervous systems integrate cellular metabolism. Special emphasis on examining the cardiovascular, pulmonary, gastrointestinal, and renal systems, as well as liver function, drug metabolism, and pharmacogenetics.
M. Krieger, D. Sabatini
Textbooks (Fall 2016)

7.21 Microbial Physiology
______

Undergrad (Fall)
(Subject meets with7.62)
Prereq: 7.03, 7.05
Units: 4-0-8
Lecture: MW11-1 (56-114) Recitation: F1 (26-314)
______
Biochemical properties of bacteria and other microorganisms that enable them to grow under a variety of conditions. Interaction between bacteria and bacteriophages. Genetic and metabolic regulation of enzyme action and enzyme formation. Structure and function of components of the bacterial cell envelope. Protein secretion with a special emphasis on its various roles in pathogenesis. Additional topics include bioenergetics, symbiosis, quorum sensing, global responses to DNA damage, and biofilms. Students taking the graduate version are expected to explore the subject in greater depth.
G. C. Walker, A. J. Sinskey
Textbooks (Fall 2016)

7.22 Developmental Biology
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 7.06
Units: 5-0-7
Subject Cancelled Subject Cancelled
______
Topics include development of animal body plans, tissue patterning, cell type determination, organogenesis, morphogenesis, stem cells, and the evolution of developmental diversity and processes. Covers experimental approaches to problems of development and evolution, such as the study of vertebrate (mouse, chick, frog, fish) and invertebrate (fly, worm) models.
R. O. Hynes, P. Reddien
Textbooks (Fall 2016)

7.23 Immunology
______

Undergrad (Fall)
(Subject meets with7.63)
Prereq: 7.06
Units: 5-0-7
Lecture: MW1-3 (56-154) Recitation: T12 (56-180) or W EVE (7 PM) (66-154) +final
______
Comprehensive survey of molecular, genetic, and cellular aspects of the immune system. Topics include innate and adaptive immunity; cells and organs of the immune system; immunoglobulin, T cell receptor, and major histocompatibility complex (MHC) proteins and genes; development and functions of B and T lymphocytes; immune responses to infections and tumors; hypersensitivity, autoimmunity, and immunodeficiencies. Particular attention to the development and function of the immune system as a whole, as studied by modern methods and techniques. Students taking the graduate version are expected to explore the subject in greater depth.
H. Ploegh, L. Steiner
Textbooks (Fall 2016)

7.26 Molecular Basis of Infectious Disease
______

Undergrad (Spring)
(Subject meets with7.66)
Prereq: 7.06
Units: 4-0-8
______
Focuses on the principles of host-pathogen interactions with an emphasis on infectious diseases of humans. Presents key concepts of pathogenesis through the study of various human pathogens. Includes critical analysis and discussion of assigned readings. Students taking the graduate version are expected to explore the subject in greater depth.
D. Kim

7.27 Principles of Human Disease
______

Undergrad (Spring)
Prereq: 7.06
Units: 4-0-8
______
Covers current understanding of and modern approaches to human disease, emphasizing the molecular and cellular basis of both genetic disease and cancer. Topics include the genetics of simple and complex traits; karyotypic analysis and positional cloning; genetic diagnosis; the roles of oncogenes and tumor suppressors in tumor initiation, progression, and treatment; the interaction between genetics and environment; animal models of human disease; cancer; aging and disease; and conventional and gene therapy treatment strategies.
D. Housman, L. Guarente

7.28 Molecular Biology
______

Undergrad (Spring)
(Subject meets with7.58)
Prereq: 7.03;Coreq: 7.05
Units: 5-0-7
______
Detailed analysis of the biochemical mechanisms that control the maintenance, expression, and evolution of prokaryotic and eukaryotic genomes. Topics covered in lecture and readings of relevant literature include: gene regulation, DNA replication, genetic recombination, and mRNA translation. Logic of experimental design and data analysis emphasized. Presentations include both lectures and group discussions of representative papers from the literature. Students taking the graduate version are expected to explore the subject in greater depth.
S. Bell

7.29[J] Cellular and Molecular Neurobiology
______

Undergrad (Spring)
(Same subject as9.09[J])
Prereq: 7.05 or 9.01
Units: 4-0-8
______
Introduction to the structure and function of the nervous system. Emphasizes the cellular properties of neurons and other excitable cells. Includes the structure and biophysical properties of excitable cells, synaptic transmission, neurochemistry, neurodevelopment, integration of information in simple systems, and detection and information coding during sensory transduction.
T. Littleton, M. Heiman

7.30A[J] Fundamentals of Ecology I
______

Undergrad (Fall); first half of term
(Same subject as1.018A[J],12.031A[J])
Prereq: None
Units: 2-0-4
Ends Oct 21. Lecture: TR11-12.30 (48-316) Recitation: M4 (48-316) or R4 (48-308)
______
Fundamentals of ecology, considering Earth as an integrated dynamic living system. Coevolution of the biosphere and geosphere, biogeochemical cycles, metabolic diversity, primary productivity, competition and the niche, trophic dynamics and food webs, population growth and limiting factors. Combination of 1.018A and 1.018B counts as REST subject.
O. Cordero, M. Follows
Textbooks (Fall 2016)

7.30B[J] Fundamentals of Ecology II
______

Undergrad (Fall); second half of term
(Same subject as1.018B[J],12.031B[J])
Prereq: 1.018A
Units: 2-0-4
Begins Oct 24. Lecture: TR11-12.30 (48-316) Recitation: M4 (48-316) or R4 (48-308) +final
______
Advanced topics in Ecology. Population modeling, global carbon cycle, climate change, geoengineering, theories of resource competition and mutualism, allometric scaling, ecological genomics, niche theory, human population growth. Applied ecology. Combination of 1.018A and 1.018B counts as REST subject.
O. Cordero, M. Follows
No required or recommended textbooks

7.31 Current Topics in Mammalian Biology: Medical Implications
______

Undergrad (Fall)
Prereq: 7.06 or permission of instructor
Units: 4-0-8
Lecture: M3,W3-5 (68-121) +final
______
Covers recent advances in mammalian cell and developmental biology with particular emphasis on approaches that utilize mouse genetics. Combines formal lectures on selected topics with readings of original papers which are discussed in class. Major emphasis on the implications of mechanisms of human genetic diseases. Topics include early mammalian development; genomic imprinting; X inactivation; embryonic stem cells; nuclear reprogramming of somatic cells; cell migration; nervous system development; and central nervous system degenerative diseases such as Alzheimer's and Huntington's disease. Limited to 20.
F. Gertler, R. Jaenisch
No required or recommended textbooks

7.32 Systems Biology
______

Undergrad (Fall)
(Subject meets with7.81[J],8.591[J])
Prereq: 18.03, 18.05; or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (4-159) Recitation: TBA +final
______
Introduction to cellular and population-level systems biology with an emphasis on synthetic biology, modeling of genetic networks, cell-cell interactions, and evolutionary dynamics. Cellular systems include genetic switches and oscillators, network motifs, genetic network evolution, and cellular decision-making. Population-level systems include models of pattern formation, cell-cell communications, and evolutionary systems biology. Students taking graduate version explore the subject in more depth.
J. Gore
Textbooks (Fall 2016)

7.33[J] Evolutionary Biology: Concepts, Models and Computation
______

Undergrad (Spring)
(Same subject as6.049[J])
Prereq: 7.03; 6.0001 or permission of instructor
Units: 3-0-9
______
Explores and illustrates how evolution explains biology, with an emphasis on computational model building for analyzing evolutionary data. Covers key concepts of biological evolution, including adaptive evolution, neutral evolution, evolution of sex, genomic conflict, speciation, phylogeny and comparative methods, life's history, coevolution, human evolution, and evolution of disease.
R. Berwick, D. Bartel

7.331[J] Infections and Inequalities: Interdisciplinary Perspectives on Global Health
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Social Sciences
(Same subject as21A.331[J],HST.431[J])
Prereq: None
Units: 3-0-9
______
Examines case studies in infectious disease outbreaks to demonstrate how human health is a product of multiple determinants, such as biology, sociocultural and historical factors, politics, economic processes, and the environment. Analyzes how structural inequalities render certain populations vulnerable to illness and explores the moral and ethical dimensions of public health and clinical interventions to promote health. Limited to 25.
E. James, D. Kim, A. Chakraborty

7.340-7.344 Advanced Undergraduate Seminar
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: 7.06 or 7.28
Units: 2-0-4 [P/D/F]
7.340: URL: https://biology.mit.edu/undergraduate/course_listings/advanced_undergraduate_seminars
7.344: URL: https://biology.mit.edu/undergraduate/course_listings/advanced_undergraduate_seminars
7.340: TBA.
7.341: TBA.
7.342: Lecture: W1-3 (4-146)
7.343: Lecture: W EVE (7-9 PM) (56-167)
7.344: Lecture: W1-3 (68-150)
______
Seminars covering topics of current interest in biology with a focus on how to understand experimental methods and design and how to critically read the primary research literature. Small class size facilitates discussions and interactions with an active research scientist. Students visit research laboratories to see firsthand how biological research is conducted. Contact Biology Education Office for topics.
H. R. Horvitz
7.340: No required or recommended textbooks
7.341: No textbook information available
7.342: No required or recommended textbooks
7.343: No required or recommended textbooks
7.344: No required or recommended textbooks

7.345-7.349 Advanced Undergraduate Seminar
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: 7.06 or 7.28
Units: 2-0-4 [P/D/F]
7.349: URL: https://biology.mit.edu/undergraduate/course_listings/advanced_undergraduate_seminars
7.345: Lecture: T3-5 (68-150)
7.346: Lecture: R11-1 (68-150)
Subject Cancelled 7.347 Cancelled
7.348: Lecture: R3-5 (68-150)
7.349: TBA.
______
Seminars covering topics of current interest in biology with a focus on how to understand experimental methods and design and how to critically read the primary research literature. Small class size facilitates discussions and interactions with an active research scientist. Students visit research laboratories to see firsthand how biological research is conducted. Contact Biology Education Office for topics.
H. R. Horvitz
7.345: No required or recommended textbooks
7.346: No required or recommended textbooks
7.348: No textbook information available
7.349: No textbook information available

7.37[J] Molecular and Engineering Aspects of Biotechnology
______

Undergrad (Spring)
(Same subject as10.441[J],20.361[J])
Prereq: 2.005, 3.012, 5.60, or 20.110; 7.06; or permission of instructor
Units: 4-0-8
Credit cannot also be received for7.371
URL: http://web.mit.edu/7.37j/
______
Covers biological and bioengineering principles underlying the development and therapeutic use of recombinant proteins and stem cells; glycoengineering of recombinant proteins; normal and pathological signaling by growth factors and their receptors; receptor trafficking; monoclonal antibodies as therapeutics; protein pharmacology and delivery; stem cell-derived tissues as therapeutics; RNA therapeutics; combinatorial protein engineering; and new antitumor drugs.
H. Lodish, L. Griffith

7.371 Biological and Engineering Principles Underlying Novel Biotherapeutics
______

Undergrad (Fall)
Prereq: 7.06
Units: 4-0-8
Credit cannot also be received for7.37,10.441,20.361
Lecture: MW3-5 (Whitehead-7TH)
______
Covers biological and bioengineering principles underlying the development and therapeutic use of recombinant proteins and immune cells. Special attention to monoclonal antibodies and engineered immune system cells as therapeutics; protein- and glyco- engineering to enhance protein function; protein pharmacology and delivery; nucleic acid- based biotherapeutics; generation of functional cells and tissues from embryonic stem cells and iPS cells; and immune cell-cancer cell interactions in cancer immunotherapy.
J. Chen, H. Lodish
Textbooks (Fall 2016)

7.38 Mechanical Cell Biology
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with7.83)
Prereq: 7.06
Units: 3-0-9
URL: http://web.mit.edu/2.75/
______
Covers current topics in eukaryotic cell biology, with a focus on understanding how physical forces are generated in cells and how these forces organize and shape cells and tissues. Combines lectures and the analysis of the primary literature to explore concepts and experimental approaches related to forces in cell biology at the molecular, cellular, and organismal level. Also considers the journal publication process, providing insights and experience into writing a cover letter, paper submission, reviewer critique, and communicating the significance of one's research. Students taking the graduate version explore the subject in greater depth.
I. Cheeseman, A. Martin

7.41 Principles of Chemical Biology
______

Undergrad (Spring)
(Subject meets with7.73)
Prereq: 7.05
Units: 3-0-9
______
Spanning the fields of biology, chemistry and engineering, class addresses the principles of chemical biology and its application of chemical and physical methods and reagents to the study and manipulation of biological systems. Topics include bioorthogonal reactions and activity-based protein profiling, small molecule inhibitors and chemical genetics, fluorescent probes for biological studies, and unnatural amino acid mutagenesis. Also covers chemical biology approaches for studying dynamic post-translational modification reactions, natural product biosynthesis and mutasynthesis, and high-throughput drug screening. Students taking the graduate version are expected to explore the subject in greater depth
B. Imperiali, J. K. Weng

7.45 The Hallmarks of Cancer
______

Undergrad (Fall)
(Subject meets with7.85)
Prereq: None.Coreq: 7.06
Units: 4-0-8
Lecture: TR1-2.30 (56-114) Recitation: R EVE (7 PM) (56-167) or F11 (4-144) or F12 (4-144) +final
______
Provides a comprehensive introduction to the fundamentals of cancer biology and cancer treatment. Topics include cancer genetics, genomics, and epigenetics; familial cancer syndromes; signal transduction, cell cycle control, and apoptosis; cancer metabolism; stem cells and cancer; metastasis; cancer immunology and immunotherapy; conventional and molecularly-targeted therapies; and early detection and prevention. Students taking graduate version complete additional assignments.
T. Jacks, M. Vander Heiden
Textbooks (Fall 2016)

7.458[J] Advances in Biomanufacturing
(New)
______

Undergrad (Fall, Spring); second half of term
(Same subject as10.03[J])
(Subject meets with7.548[J],10.53[J])
Prereq: None
Units: 1-0-2 [P/D/F]
Begins Oct 24. Lecture: TR11 (66-148)
______
Seminar examines how biopharmaceuticals, an increasingly important class of pharmaceuticals, are manufactured. Topics range from fundamental bioprocesses to new technologies to the economics of biomanufacturing. Also covers the impact of globalization on regulation and quality approaches as well as supply chain integrity. Students taking graduate version complete additional assignments.
J. C. Love, A. Sinskey, S. Springs
No textbook information available

7.49[J] Developmental Neurobiology
______

Undergrad (Spring)
(Same subject as9.18[J])
(Subject meets with7.69[J],9.181[J])
Prereq: 9.01, 7.03, 7.05, or permission of instructor
Units: 3-0-9
______
Considers molecular control of neural specification, formation of neuronal connections, construction of neural systems, and the contributions of experience to shaping brain structure and function. Topics include: neural induction and pattern formation, cell lineage and fate determination, neuronal migration, axon guidance, synapse formation and stabilization, activity-dependent development and critical periods, development of behavior. Students taking graduate version complete additional readings that will be addressed in their mid-term and final exams.
E. Nedivi, M. Heiman

7.391 Independent Study in Biology
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

7.392 Independent Study in Biology
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No required or recommended textbooks

7.393 Independent Study in Genetics
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No required or recommended textbooks

7.394 Independent Study in Biochemistry
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No required or recommended textbooks

7.395 Independent Study in Cell and Molecular Biology
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No required or recommended textbooks

7.396 Independent Study in Experimental Biology
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Program of study or research to be arranged with a department faculty member.
Staff
No required or recommended textbooks

7.S390 Special Subject in Biology
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

7.S391 Special Subject in Biology
______

Undergrad (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

7.S392 Special Subject in Biology
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff

7.S399 Special Subject in Biology
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff

7.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of department.
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

7.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of department
Units arranged
TBA.
______
Undergraduate research opportunities in the Department of Biology. For further information, consult departmental coordinator, Gene Brown.
Staff
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

Graduate Subjects

MIT-WHOI Joint Program in Oceanography

7.410 Applied Statistics
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
Provides an introduction to modern applied statistics. Topics include likelihood-based methods for estimation, confidence intervals, and hypothesis-testing; bootstrapping; time series modeling; linear models; nonparametric regression; and model selection. Organized around examples drawn from the recent literature.
A. Solow

7.411 Seminars in Biological Oceanography
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
Meets at WHOI. TBA.
______
Selected topics in biological oceanography.
WHOI Staff
No textbook information available

7.421 Problems in Biological Oceanography
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
Meets at WHOI. TBA.
______
Advanced problems in biological oceanography with assigned reading and consultation.
Information: M. Neubert (WHOI)
No textbook information available

7.430 Topics in Quantitative Marine Science
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussions on quantitative marine ecology. Topics vary from year to year.
WHOI Staff
No textbook information available

7.431 Topics in Marine Ecology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussions on ecological principles and processes in marine populations, communities, and ecosystems. Topics vary from year to year.
WHOI Staff
No textbook information available

7.432 Topics in Marine Physiology and Biochemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussions on physiological and biochemical processes in marine organisms. Topics vary from year to year.
WHOI Staff
No textbook information available

7.433 Topics in Biological Oceanography
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussions on biological oceanography. Topics vary from year to year.
WHOI Staff
No textbook information available

7.434 Topics in Zooplankton Biology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussions on the biology of marine zooplankton. Topics vary from year to year.
WHOI Staff
No textbook information available

7.435 Topics in Benthic Biology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussions on the biology of marine benthos. Topics vary from year to year.
WHOI Staff
No textbook information available

7.436 Topics in Phytoplankton Biology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussion on the biology of marine phytoplankton. Topics vary from year to year.
WHOI Staff
No textbook information available

7.437 Topics in Molecular Biological Oceanography
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussion on molecular biological oceanography. Topics vary from year to year.
WHOI Staff
No textbook information available

7.438 Topics in the Behavior of Marine Animals
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussion on the behavioral biology of marine animals. Topics vary from year to year.
WHOI Staff
No textbook information available

7.439 Topics in Marine Microbiology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
Meets at WHOI. TBA.
______
Lectures and discussion on the biology of marine prokaryotes. Topics vary from year to year.
WHOI Staff
No textbook information available

7.440 An Introduction to Mathematical Ecology
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Calculus I (GIR), 7.30B, or permission of instructor
Units: 3-0-9
______
Covers the basic models of population growth, demography, population interaction (competition, predation, mutualism), food webs, harvesting, and infectious disease, and the mathematical tools required for their analysis. Because these tools are also basic to the analysis of models in biochemistry, physiology, and behavior, subject also broadly relevant to students whose interests are not limited to ecological problems.
M. Neubert, H. Caswell (WHOI)

7.470 Biological Oceanography
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Intended for students with advanced training in biology. Intensive overview of biological oceanography. Major paradigms discussed, and dependence of biological processes in the ocean on physical and chemical aspects of the environment examined. Surveys the diversity of marine habitats, major groups of taxa inhabiting those habitats, and the general biology of the various taxa: the production and consumption of organic material in the ocean, as well as factors controlling those processes. Species diversity, structure of marine food webs, and the flow of energy within different marine habitats are detailed and contrasted.
WHOI Staff

7.491 Research in Biological Oceanography
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
Meets at WHOI. TBA.
______
Directed research in biological oceanography not leading to graduate thesis and initiated prior to the qualifying exam.
WHOI Staff
No textbook information available

Microbiology (MICRO)

7.492[J] Methods and Problems in Microbiology
______

Graduate (Fall)
(Same subject as1.86[J],20.445[J])
Prereq: None
Units: 3-0-9
Lecture: W EVE (3-6 PM) (4-146)
______
Students will read and discuss primary literature covering key areas of microbial research with emphasis on methods and approaches used to understand and manipulate microbes. Preference to first-year Microbiology and Biology students.
M. Laub
No required or recommended textbooks

7.493[J] Microbial Genetics and Evolution
______

Graduate (Fall)
(Same subject as1.87[J],12.493[J],20.446[J])
Prereq: 7.03, 7.05, or permission of instructor
Units: 4-0-8
Lecture: TR12.30-2.30 (66-160)
______
Covers aspects of microbial genetic and genomic analyses, central dogma, horizontal gene transfer, and evolution.
A. D. Grossman, G. Fournier
Textbooks (Fall 2016)

7.494 Research Problems in Microbiology
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Directed research in the fields of microbial science and engineering.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

7.498 Teaching Experience in Microbiology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
For qualified graduate students in the Microbiology graduate program interested in teaching. Classroom or laboratory teaching under the supervision of a faculty member.
Staff
No required or recommended textbooks

7.499 Research Rotations in Microbiology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor;Coreq: 7.492, or 7.493
Units arranged [P/D/F]
TBA.
______
Introduces students to faculty participating in the interdepartmental Microbiology graduate program through a series of three lab rotations, which provide broad exposure to microbiology research at MIT. Students select a lab for thesis research by the end of their first year. Given the interdisciplinary nature of the program and the many research programs available, students may be able to work jointly with more than one research supervisor. Limited to students in the Microbiology graduate program.
Staff
No required or recommended textbooks

7.MTHG Microbiology Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of a PhD thesis. To be arranged by the student and the appropriate MIT faculty member.
Staff
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

Biology

7.50 Method and Logic in Molecular Biology
______

Graduate (Fall)
Prereq: Permission of instructor orCoreq: 7.51, 7.52
Units: 4-0-8
1st mtg Sept 8 at 2.30 pm. Recitation: M3-6,R2.30-5.30 (68-180, 68-156, Whitehead-7TH)
______
Logic, experimental design and methods in biology, using discussions of the primary literature to discern the principles of biological investigation in making discoveries and testing hypotheses. In collaboration with faculty, students also apply those principles to generate a potential research project, presented in both written and oral form. Limited to Course 7 graduate students.
Staff
No required or recommended textbooks

7.51 Principles of Biochemical Analysis
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 6-0-6
Friday recitation in 66-168. Lecture: MWF9-10.30 (56-114) Recitation: T2.30,F1 (66-144)
______
Principles of biochemistry, emphasizing structure, equilibrium studies, kinetics, informatics, single-molecule studies, and experimental design. Topics include macromolecular binding and specificity, protein folding and unfolding, allosteric systems, transcription factors, kinases, membrane channels and transporters, and molecular machines.
A. Keating, R. T. Sauer
No required or recommended textbooks

7.52 Genetics for Graduate Students
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 4-0-8
Lecture: TR9.30-11.30 (56-154) Recitation: W3.30 (26-314) or F2.30 (26-210)
______
Principles and approaches of genetic analysis, including Mendelian inheritance and prokaryotic genetics, yeast genetics, developmental genetics, neurogenetics, and human genetics.
A. Amon, D. Housman, H. R. Horvitz
Textbooks (Fall 2016)

7.540[J] Frontiers in Chemical Biology
______

Graduate (Fall)
(Same subject as5.54[J],20.554[J])
Prereq: 5.13, 5.07, 7.06, permission of instructor
Units: 2-0-4
Lecture: R8.30-10 (4-231)
______
Introduction to current research at the interface of chemistry, biology, and bioengineering. Topics include imaging of biological processes, metabolic pathway engineering, protein engineering, mechanisms of DNA damage, RNA structure and function, macromolecular machines, protein misfolding and disease, metabolomics, and methods for analyzing signaling network dynamics. Lectures are interspersed with class discussions and student presentations based on current literature.
M. Shoulders
No textbook information available

7.547[J] Principles and Practice of Drug Development
______

Graduate (Fall)
(Same subject as10.547[J],15.136[J],HST.920[J],IDS.620[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://hst-hu-mit.mit.edu/courses/HST920
Lecture: W EVE (3-6 PM) (1-190)
______
Description and critical assessment of the major issues and stages of developing a pharmaceutical or biopharmaceutical. Drug discovery, preclinical development, clinical investigation, manufacturing and regulatory issues considered for small and large molecules. Economic and financial considerations of the drug development process. Multidisciplinary perspective from faculty in clinical; life; and management sciences; as well as industry guests.
T. J. Allen, C. L. Cooney, S. N. Finkelstein, A. J. Sinskey, G. K. Raju
No textbook information available

7.548[J] Advances in Biomanufacturing
(New)
______

Graduate (Fall, Spring); second half of term
(Same subject as10.53[J])
(Subject meets with 7.458[J],10.03[J])
Prereq: None
Units: 1-0-2
Begins Oct 24. Lecture: TR11 (66-148)
______
Seminar examines how biopharmaceuticals, an increasingly important class of pharmaceuticals, are manufactured. Topics range from fundamental bioprocesses to new technologies to the economics of biomanufacturing. Also covers the impact of globalization on regulation and quality approaches as well as supply chain integrity. Students taking graduate version complete additional assignments.
J. C. Love, A. Sinskey, S. Springs
No textbook information available

7.549[J] Case Studies and Strategies in Drug Discovery and Development
______

Graduate (Spring)
(Same subject as15.137[J],20.486[J],HST.916[J])
Prereq: None
Units: 2-0-4
URL: http://mit.edu/7.549j
______
Aims to develop appreciation for the stages of drug discovery and development, from target identification, to the submission of preclinical and clinical data to regulatory authorities for marketing approval. Following introductory lectures on the process of drug development, students working in small teams analyze how one of four new drugs or drug candidates traversed the discovery/development landscape. For each case, an outside expert from the sponsoring drug company or pivotal clinical trial principal investigator provides guidance and critiques the teams' presentations to the class.
S. R. Tannenbaum, A. J. Sinskey, A. W. Wood

7.55 Case Studies in Modern Experimental Design
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 2-0-7
______
Focuses on enhancing students' ability to analyze, design and present experiments, emphasizing modern techniques. Class discussions begin with papers that developed or utilized contemporary approaches (e.g., quantitative microscopy, biophysical and molecular genetic methods) to address important problems in biology. Each student prepares one specific aim of a standard research proposal for a project that emphasizes research strategy, experimental design, and writing.
L. Guarente, F. Solomon

7.57 Quantitative Biology for Graduate Students
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 4-0-8
______
Introduces the fundamental concepts and tools of quantitative approaches to molecular and cellular biology. Covers a wide range of mathematical, computational, and statistical methods, although no previous expertise in these areas is required. Focuses on understanding quantitative approaches through the analysis of particular problems and examples drawn from classical genetics, molecular biology, cell biology, genomics, and systems biology.
P. Gupta, A. Regev

7.58 Molecular Biology
______

Graduate (Spring)
(Subject meets with7.28)
Prereq: 7.03, 7.05, permission of instructor
Units: 5-0-7
______
Detailed analysis of the biochemical mechanisms that control the maintenance, expression, and evolution of prokaryotic and eukaryotic genomes. Topics covered in lecture and readings of relevant literature include: gene regulation, DNA replication, genetic recombination, and mRNA translation. Logic of experimental design and data analysis emphasized. Presentations include both lectures and group discussions of representative papers from the literature. Students taking the graduate version are expected to explore the subject in greater depth.
S. Bell

7.59[J] Teaching College-Level Science and Engineering
______

Graduate (Fall)
(Same subject as1.95[J],5.95[J],8.395[J],18.094[J])
(Subject meets with2.978)
Prereq: None
Units: 2-0-2 [P/D/F]
URL: https://wikis.mit.edu/confluence/pages/viewpage.action?pageId=110876412
Lecture: R9-11 (4-149)
______
Participatory seminar focuses on the knowledge and skills necessary for teaching science and engineering in higher education. Topics include theories of adult learning; course development; promoting active learning, problemsolving, and critical thinking in students; communicating with a diverse student body; using educational technology to further learning; lecturing; creating effective tests and assignments; and assessment and evaluation. Students research and present a relevant topic of particular interest. Appropriate for both novices and those with teaching experience.
J. Rankin
No textbook information available

7.60 Cell Biology: Structure and Functions of the Nucleus
______

Graduate (Spring)
Prereq: 7.06
Units: 4-0-8
______
Eukaryotic genome structure, function, and expression, processing of RNA, and regulation of the cell cycle. Emphasis on the techniques and logic used to address important problems in nuclear cell biology. Lectures on broad topic areas in nuclear cell biology and discussions on representative recent papers.
R. Young, L. Boyer

7.61 Eukaryotic Cell Biology: Principles and Practice
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 4-0-8
Lecture: MW1-3 (E25-117) +final
______
Emphasizes methods and logic used to analyze structure and function of eukaryotic cells in diverse systems (e.g., yeast, fly, worm, mouse, human; development, stem cells, neurons). Combines lectures and in-depth roundtable discussions of literature readings with the active participation of faculty experts. Focuses on membranes (structure, function, traffic), organelles, the cell surface, signal transduction, cytoskeleton, cell motility and extracellular matrix. Ranges from basic studies to applications to human disease, while stressing critical analysis of experimental approaches. Enrollment limited.
R. O. Hynes, M. Krieger
Textbooks (Fall 2016)

7.62 Microbial Physiology
______

Graduate (Fall)
(Subject meets with7.21)
Prereq: 7.03, 7.05, permission of instructor
Units: 4-0-8
Lecture: MW11-1 (56-114) Recitation: F1 (26-314)
______
Biochemical properties of bacteria and other microorganisms that enable them to grow under a variety of conditions. Interaction between bacteria and bacteriophages. Genetic and metabolic regulation of enzyme action and enzyme formation. Structure and function of components of the bacterial cell envelope. Protein secretion with a special emphasis on its various roles in pathogenesis. Additional topics include bioenergetics, symbiosis, quorum sensing, global responses to DNA damage, and biofilms. Students taking the graduate version are expected to explore the subject in greater depth.
G. C. Walker, A. J. Sinskey
Textbooks (Fall 2016)

7.63 Immunology
______

Graduate (Fall)
(Subject meets with7.23)
Prereq: 7.06, permission of instructor
Units: 5-0-7
Lecture: MW1-3 (56-154) +final
______
Comprehensive survey of molecular, genetic, and cellular aspects of the immune system. Topics include innate and adaptive immunity; cells and organs of the immune system; immunoglobulin, T cell receptor, and major histocompatibility complex (MHC) proteins and genes; development and functions of B and T lymphocytes; immune responses to infections and tumors; hypersensitivity, autoimmunity, and immunodeficiencies. Particular attention to the development and function of the immune system as a whole, as studied by modern methods and techniques. Students taking the graduate version are expected to explore the subject in greater depth.
H. Ploegh, L. Steiner
Textbooks (Fall 2016)

7.64 Molecular Mechanisms, Pathology and Therapy of Human Neuromuscular Disorders
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Investigates the molecular and clinical basis of central nervous system and neuromuscular disorders with particular emphasis on strategies for therapeutic intervention. Considers the in-depth analysis of clinical features, pathological mechanisms, and responses to current therapeutic interventions. Covers neurodegenerative diseases, such as Huntington's disease, Parkinson's disease, Alzheimer's disease, Amyotropic Lateral Schlerosis, Frontal Temporal Dementia, and neuromuscular disorders, such as Myotonic Dystrophy, Facio Scapular Humoral Dystrophy, and Duchenne Muscular Dystrophy.
D. Housman

7.65[J] Molecular and Cellular Neuroscience Core I
______

Graduate (Fall)
(Same subject as9.015[J])
Prereq: None
Units: 3-0-9
Lecture: TR1-2.30 (46-4062)
______
Survey and primary literature review of major topic areas in molecular and cellular neurobiology. Covers neurogenomics, nervous system formation, axonal pathfinding, cytoskeletal regulation, synapse formation, neurotransmitter release, and cellular neurophysiology. Includes lectures and weekly paper write-ups, together with student presentations and discussion of primary literature. A final two-page research write-up is also due at the end of the term.
J. T. Littleton, H. Sive, F. Gertler
No required or recommended textbooks

7.66 Molecular Basis of Infectious Disease
______

Graduate (Spring)
(Subject meets with7.26)
Prereq: 7.06, permission of instructor
Units: 4-0-8
______
Focuses on the principles of host-pathogen interactions with an emphasis on infectious diseases of humans. Presents key concepts of pathogenesis through the study of various human pathogens. Includes critical analysis and discussion of assigned readings. Students taking the graduate version are expected to explore the subject in greater depth.
D. Kim

7.67[J] Genetic Methods in Neurobiology
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as9.322[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://mit.edu/7.67j/
______
Presents selected topics in which genetic analysis informs neurobiological issues, including action potential conduction and synaptic release in Drosophila, axon guidance in nematodes and Drosophila, olfaction and orienting behavior in nematodes. Studies hippocampal and cortical circuitry and function in mice, as well as genetically-determined and genetically-influenced human traits and diseases. Reviews methods such as mutagenesis, gene knockouts and transgene constructs, tissue-specific expression vectors, optically, chemically and thermally-inducible gene activation and inactivation.
W. G. Quinn

7.68[J] Molecular and Cellular Neuroscience Core II
______

Graduate (Spring)
(Same subject as9.013[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Survey and primary literature review of major areas in molecular and cellular neurobiology. Covers genetic neurotrophin signaling, adult neurogenesis, G-protein coupled receptor signaling, glia function, epigenetics, neuronal and homeostatic plasticity, neuromodulators of circuit function, and neurological/psychiatric disease mechanisms. Includes lectures and exams, and involves presentation and discussion of primary literature. 9.015 recommended, though the core subjects can be taken in any sequence.
G. Feng, L.-H. Tsai

7.69[J] Developmental Neurobiology
______

Graduate (Spring)
(Same subject as9.181[J])
(Subject meets with 7.49[J],9.18[J])
Prereq: 9.011 or permission of instructor
Units: 3-0-9
______
Considers molecular control of neural specification, formation of neuronal connections, construction of neural systems, and the contributions of experience to shaping brain structure and function. Topics include: neural induction and pattern formation, cell lineage and fate determination, neuronal migration, axon guidance, synapse formation and stabilization, activity-dependent development and critical periods, development of behavior. In addition to final exam, analysis and presentation of research papers required for final grade. Students taking graduate version complete additional assignments. Students taking graduate version complete additional readings that will be addressed in their mid-term and final exams.
E. Nedivi, M. Heiman

7.70 Regulation of Gene Expression
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 4-0-8
______
Seminar examines basic principles of biological regulation of gene expression. Focuses on examples that underpin these principles, as well as those that challenge certain long-held views. Topics covered may include the role of transcription factors, enhancers, DNA modifications, non-coding RNAs, and chromatin structure in the regulation of gene expression and mechanisms for epigenetic inheritance of transcriptional states. Limited to 40.
L. Boyer, M. Gehring

7.71 Biophysical Chemistry Techniques
______

Graduate (Spring)
(Subject meets with5.78)
Prereq: 5.13, 5.60; 5.07 or 7.05
Units: 5-0-7
URL: http://web.mit.edu/5.78/www/
______
For students who want to understand the benefits and caveats of biophysical techniques used to ascertain the structure of macromolecules, especially on the 3-D level. The first half of the course focuses on x-ray crystallography, the single most important technique used in determining the 3-D structure of macromolecules. Discussion of crystallographic theory is complemented with exercises such as crystallization, data processing, and model building. In the second half of the course, biophysical techniques are covered that supplement the 3-D characterization of biological macromolecules. Topics include CD spectroscopy, isothermal calorimetry, analytical ultracentrifugation, dynamic light scattering, and surface plasmon resonance (BIAcore). Theoretical principles behind the techniques are covered, applications are discussed, and students are performing practical exercises using instrumentation available at MIT. Meets with 5.78 when offered concurrently.
C. Drennan, T. Schwartz

7.72 Principles and Frontiers of Developmental Biology
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 4-0-8
Lecture: MW11-1 (Whitehead-705)
______
Covers fundamental principles and frontiers of animal development. Focuses on molecular mechanisms, experimental approaches, evolutionary context, human disorders, and topics of societal importance. Compares vertebrate (mouse, chick, frog, fish) and invertebrate (fly, worm) models. Modules include patterning and asymmetry of the body plan, cell type determination and diversity, organogenesis, morphogenesis, maternal control, organismal growth, stem cells, tissue engineering, and issues in human development.
H. Sive, T. Orr-Weaver
Textbooks (Fall 2016)

7.73 Principles of Chemical Biology
(New)
______

Graduate (Spring)
(Subject meets with7.41)
Prereq: 7.05; Permission of instructor
Units: 3-0-9
______
Spanning the fields of biology, chemistry and engineering, class addresses the principles of chemical biology and its application of chemical and physical methods and reagents to the study and manipulation of biological systems. Topics include bioorthogonal reactions and activity-based protein profiling, small molecule inhibitors and chemical genetics, fluorescent probes for biological studies, and unnatural amino acid mutagenesis. Also covers chemical biology approaches for studying dynamic post-translational modification reactions, natural product biosynthesis and mutasynthesis, and high-throughput drug screening. Students taking the graduate version are expected to explore the subject in greater depth.
B. Imperiali, J. K. Weng

7.74[J] Topics in Biophysics and Physical Biology
______

Graduate (Fall)
(Same subject as8.590[J],20.416[J])
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: F1-2.30 (56-167)
______
Provides broad exposure to research in biophysics and physical biology, with emphasis on the critical evaluation of scientific literature. Weekly meetings include in-depth discussion of scientific literature led by distinct faculty on active research topics. Each session also includes brief discussion of non-research topics including effective presentation skills, writing papers and fellowship proposals, choosing scientific and technical research topics, time management, and scientific ethics.
I. Cisse, N. Fakhri, M. Guo
No required or recommended textbooks

7.76 Topics in Macromolecular Structure and Function
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
______
In-depth analysis and discussion of classic and current literature, with an emphasis on the structure, function, and mechanisms of proteins and other biological macromolecules.
C. Drennan, R. T. Sauer

7.77 Nucleic Acids, Structure, Function, Evolution and Their Interactions with Proteins
______

Graduate (Spring)
Prereq: 7.05 or 7.51
Units: 3-0-9
______
Surveys primary literature, focusing on biochemical, biophysical, genetic, and combinatorial approaches for understanding nucleic acids. Topics include the general properties, functions, and structural motifs of DNA and RNA; RNAs as catalysts and as regulators of gene expression; RNA editing and surveillance, and the interaction of nucleic acids with proteins, such as zinc-finger proteins, modification enzymes, aminoacyl-tRNA synthetases and other proteins of the translational machinery. Includes some lectures but is mostly analysis and discussion of current literature in the context of student presentations.
D. Bartel, U. RajBhandary

7.80 Biological Chemistry II
______

Graduate (Spring)
(Subject meets with5.08[J],7.08[J])
Prereq: 5.12; 5.07 or 7.05
Units: 4-0-8
______
More advanced treatment of biochemical mechanisms that underlie biological processes. Topics include macromolecular machines such as the ribosome, the proteosome, fatty acid synthases as a paradigm for polyketide synthases and non-ribosomal polypeptide synthases, and polymerases. Emphasis is on experimental methods used to unravel these processes and how these processes fit into the cellular context and coordinate regulation. Students taking the graduate version are expected to explore the subject in greater depth.
J. Stubbe, E. Nolan

7.81[J] Systems Biology
______

Graduate (Fall)
(Same subject as8.591[J])
(Subject meets with7.32)
Prereq: 18.03, 18.05; or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (4-159) Recitation: TBA +final
______
Introduction to cellular and population-level systems biology with an emphasis on synthetic biology, modeling of genetic networks, cell-cell interactions, and evolutionary dynamics. Cellular systems include genetic switches and oscillators, network motifs, genetic network evolution, and cellular decision-making. Population-level systems include models of pattern formation, cell-cell communication, and evolutionary systems biology. Students taking graduate version explore the subject in more depth.
J. Gore
Textbooks (Fall 2016)

7.82 Topics of Mammalian Development and Genetics
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9 [P/D/F]
______
Seminar covering embryologic, molecular, and genetic approaches to development in mice and humans. Topics include preimplantation development; gastrulation; embryonic stem cells, gene targeting and nuclear reprogramming of somatic cells; genomic imprinting; X-inactivation; sex determination; and germ cells.
R. Jaenisch, R. Young

7.83 Mechanical Cell Biology
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with7.38)
Prereq: 7.06, permission of instructor
Units: 3-0-9
______
Covers current topics in eukaryotic cell biology, with a focus on understanding how physical forces are generated in cells and how these forces organize and shape cells and tissues. Combines lectures and the analysis of the primary literature to explore concepts and experimental approaches related to forces in cell biology at the molecular, cellular, and organismal level. Also considers the journal publication process, providing insights and experience into writing a cover letter, paper submission, reviewer critique, and communicating the significance of one's research. Students taking the graduate version explore the subject in greater depth.
I. Cheeseman, A. Martin

7.85 The Hallmarks of Cancer
______

Graduate (Fall)
(Subject meets with7.45)
Prereq: Permission of instructor;Coreq: 7.06
Units: 4-0-8
Lecture: TR1-2.30 (56-114) Recitation: R EVE (7 PM) (56-167) or F11 (4-144) or F12 (4-144) +final
______
Provides a comprehensive introduction to the fundamentals of cancer biology and cancer treatment. Topics include cancer genetics, genomics, and epigenetics; familial cancer syndromes; signal transduction, cell cycle control, and apoptosis; cancer metabolism; stem cells and cancer; metastasis; cancer immunology and immunotherapy; conventional and molecularly-targeted therapies; and early detection and prevention. Students taking graduate version complete additional assignments.
T. Jacks, M. Vander Heiden
Textbooks (Fall 2016)

7.87 Protein Folding and Misfolding in Biology
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 7.51, 7.52; or permission of instructor
Units: 3-0-6
______
Covers protein folding, misfolding, aggregation, and amyloid formation in the context of biological systems. Addresses topics such as chaperone structure and function, biofilm formation by bacteria, protein-folding diseases (including but not limited to Alzheimer's, Parkinson's, and Huntington's diseases), the process of therapeutics discovery for drugs and biologics. Features guest lectures and Skype discussions with international leaders in the field. Students present papers covering mutually agreed-upon topics of interest.
S. Lindquist

7.89[J] Topics in Computational and Systems Biology
______

Graduate (Fall)
(Same subject asCSB.100[J])
Prereq: Permission of instructor
Units: 2-0-10
Lecture: F11-1 (66-148)
______
Seminar based on research literature. Papers covered are selected to illustrate important problems and varied approaches in the field of computational and systems biology, and to provide students a framework from which to evaluate new developments. Preference to first-year CSB PhD students.
C. Burge
No textbook information available

7.931 Independent Study in Biology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

7.932 Independent Study in Biology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of study or research to be arranged with a department faculty member.
Staff
No required or recommended textbooks

7.933 Research Rotations in Biology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Introduces students to faculty participating in the Biology graduate program through a series of lab rotations, which provide broad exposure to biology research at MIT. Students select a lab for thesis research by the end of their first year. Limited to students in the Biology graduate program.
Staff
No required or recommended textbooks

7.934 Teaching Experience in Biology
______

Graduate (Fall, Spring)
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
For qualified graduate students in the Biology graduate program interested in teaching. Classroom or laboratory teaching under the supervision of a faculty member.
Staff
No required or recommended textbooks

7.935 Responsible Conduct in Biology
______

Graduate (Fall)
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Sessions focus on the responsible conduct of science. Considers recordkeeping and reporting; roles of mentor and mentee; authorship, review, and confidentiality; resolving conflicts; misfeasance and malfeasance; collaborations, competing interests, and intellectual property; and proper practices in the use of animal and human subjects. Limited to second-year graduate students in Biology.
Staff
No required or recommended textbooks

7.941 Research Problems
______

Graduate (Fall, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

7.942 Research Problems
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Directed research in a field of biological science, but not contributory to graduate thesis.
Consult Biology Education Office

7.95 Cancer Biology
______

Graduate (Spring)
Prereq: 7.85, permission of instructor
Units: 3-0-9
______
Advanced seminar involving intensive analysis of historical and current developments in cancer biology. Topics address principles of apoptosis, principles of cancer biology, cancer genetics, cancer cell metabolism, tumor immunology, and therapy. Detailed analysis of research literature, including important reports published in recent years. Enrollment limited.
R. Weinberg, O. Yilmaz

7.98[J] Neural Plasticity in Learning and Memory
______

Graduate (Spring)
(Same subject as9.301[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://web.mit.edu/7.98/
______
Examination of the role of neural plasticity during learning and memory of invertebrates and mammals. Detailed critical analysis of the current literature of molecular, cellular, genetic, electrophysiological, and behavioral studies. Student-directed presentations and discussions of original papers supplemented by introductory lectures. Juniors and seniors require instructor's permission.
S. Tonegawa, W. Quinn

7.S930 Special Subject in Biology
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

7.S931 Special Subject in Biology
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

7.S932 Special Subject in Biology
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff

7.S939 Special Subject in Biology
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Covers material in various fields of biology not offered by the regular subjects of instruction.
Staff

7.THG Graduate Biology Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of a Ph.D. thesis; to be arranged by the student and an appropriate MIT faculty member.
Staff
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|7.00-7.999 plus UROP and Thesis|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 8: Physics
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Course 8: Physics
Fall 2016


Undergraduate Subjects

8.01 Physics I
______

Undergrad (Fall) Physics I
Prereq: None
Units: 3-2-7
Credit cannot also be received for8.011,8.012,8.01L,CC.801,CC.8012,ES.801,ES.8012
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW9-11,F9 (26-152) or MW11-1,F11 (26-152) or MW1-3,F1 (26-152) or MW3-5,F4 (26-152) or TR9-11,F10 (26-152) or TR11-1,F12 (26-152) or TR2-4,F3 (26-152) +final
______
Introduces classical mechanics. Space and time: straight-line kinematics; motion in a plane; forces and static equilibrium; particle dynamics, with force and conservation of momentum; relative inertial frames and non-inertial force; work, potential energy and conservation of energy; kinetic theory and the ideal gas; rigid bodies and rotational dynamics; vibrational motion; conservation of angular momentum; central force motions; fluid mechanics. Subject taught using the TEAL (Technology-Enabled Active Learning) format which features students working in groups of three, discussing concepts, solving problems, and doing table-top experiments with the aid of computer data acquisition and analysis.
D. Chakrabarty, P. Dourmashkin
Textbooks (Fall 2016)

8.011 Physics I
______

Undergrad (Spring) Physics I
Prereq: None
Units: 5-0-7
Credit cannot also be received for8.01,8.012,8.01L,CC.801,CC.8012,ES.801,ES.8012
URL: http://web.mit.edu/physics/subjects/index.html
______
Introduces classical mechanics. Space and time: straight-line kinematics; motion in a plane; forces and equilibrium; experimental basis of Newton's laws; particle dynamics; universal gravitation; collisions and conservation laws; work and potential energy; vibrational motion; conservative forces; inertial forces and non-inertial frames; central force motions; rigid bodies and rotational dynamics. Designed for students with previous experience in 8.01; the subject is designated as 8.01 on the transcript.
Staff

8.012 Physics I
______

Undergrad (Fall) Physics I
Prereq: None
Units: 5-0-7
Credit cannot also be received for8.01,8.011,8.01L,CC.801,CC.8012,ES.801,ES.8012
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR9-10.30 (6-120) Lab: TBA Recitation: MW10 (26-322) or MW11 (26-322) or MW1 (26-314) or MW2 (26-314) +final
______
Elementary mechanics, presented in greater depth than in 8.01. Newton's laws, concepts of momentum, energy, angular momentum, rigid body motion, and non-inertial systems. Uses elementary calculus freely; concurrent registration in a math subject more advanced than 18.01 is recommended. In addition to covering the theoretical subject matter, students complete a small experimental project of their own design. Freshmen admitted via AP or Math Diagnostic for Physics Placement results.
M. Soljacic
Textbooks (Fall 2016)

8.01L Physics I
______

Undergrad (Fall, IAP) Physics I
Prereq: None
Units: 3-2-7
Credit cannot also be received for8.01,8.011,8.012,CC.801,CC.8012,ES.801,ES.8012
URL: http://web.mit.edu/physics/subjects/index.html
Final exam during iap. Lecture: MWF9 (6-120) Recitation: TR10 (32-082) or TR11 (32-082) or TR12 (32-082) or TR1 (32-082) or TR2 (2-135) or TR3 (2-135)
______
Introduction to classical mechanics (see description under 8.01). Includes components of the TEAL (Technology-Enabled Active Learning) format. Material covered over a longer interval so that the subject is completed by the end of the IAP. Substantial emphasis given to reviewing and strengthening necessary mathematics tools, as well as basic physics concepts and problem-solving skills. Content, depth, and difficulty is otherwise identical to that of 8.01. The subject is designated as 8.01 on the transcript.
P. Jarillo-Herrero
Textbooks (Fall 2016)

8.02 Physics II
______

Undergrad (Fall, Spring) Physics II
Prereq: Physics I (GIR), Calculus I (GIR)
Units: 3-2-7
Credit cannot also be received for8.021,8.022,CC.802,CC.8022,ES.802,ES.8022
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW9-11,F9 (32-082) or MW11-1,F11 (32-082) +final
______
Introduction to electromagnetism and electrostatics: electric charge, Coulomb's law, electric structure of matter; conductors and dielectrics. Concepts of electrostatic field and potential, electrostatic energy. Electric currents, magnetic fields and Ampere's law. Magnetic materials. Time-varying fields and Faraday's law of induction. Basic electric circuits. Electromagnetic waves and Maxwell's equations. Subject taught using the TEAL (Technology Enabled Active Learning) studio format which utilizes small group interaction and current technology to help students develop intuition about, and conceptual models of, physical phenomena.
R. Redwine, K. Perez
Textbooks (Fall 2016)

8.021 Physics II
______

Undergrad (Fall) Physics II
Prereq: Physics I (GIR), Calculus I (GIR), permission of instructor
Units: 5-0-7
Credit cannot also be received for8.02,8.022,CC.802,CC.8022,ES.802,ES.8022
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR1-2.30 (35-310) Lab: F1 (35-310) Recitation: W1 (35-310) +final
______
Introduction to electromagnetism and electrostatics: electric charge, Coulomb's law, electric structure of matter; conductors and dielectrics. Concepts of electrostatic field and potential, electrostatic energy. Electric currents, magnetic fields and Ampere's law. Magnetic materials. Time-varying fields and Faraday's law of induction. Basic electric circuits. Electromagnetic waves and Maxwell's equations. Designed for students with previous experience in 8.02; the subject is designated as 8.02 on the transcript. Enrollment limited.
E. Katsavounidis
Textbooks (Fall 2016)

8.022 Physics II
______

Undergrad (Fall, Spring) Physics II
Prereq: Physics I (GIR),Coreq: Calculus II (GIR)
Units: 5-0-7
Credit cannot also be received for8.02,8.021,CC.802,CC.8022,ES.802,ES.8022
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR2-3.30 (6-120) Recitation: WF10 (26-302) or WF11 (26-302) or WF12 (26-302) or WF1 (26-302) +final
______
Parallel to 8.02, but more advanced mathematically. Some knowledge of vector calculus assumed. Maxwell's equations, in both differential and integral form. Electrostatic and magnetic vector potential. Properties of dielectrics and magnetic materials. In addition to the theoretical subject matter, several experiments in electricity and magnetism are performed by the students in the laboratory.
J. Checkelsky
Textbooks (Fall 2016)

8.03 Physics III
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR), Physics II (GIR)
Units: 5-0-7
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR11.30-1 (6-120) Recitation: MW10 (26-314) or MW11 (26-314) or MW1 (26-328) or MW2 (26-328) +final
______
Mechanical vibrations and waves; simple harmonic motion, superposition, forced vibrations and resonance, coupled oscillations, and normal modes; vibrations of continuous systems; reflection and refraction; phase and group velocity. Optics; wave solutions to Maxwell's equations; polarization; Snell's Law, interference, Huygens's principle, Fraunhofer diffraction, and gratings.
Y-J. Lee
Textbooks (Fall 2016)

8.033 Relativity
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Physics II (GIR), Calculus II (GIR)
Units: 5-0-7
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW2.30-4 (6-120) Recitation: TR10 (26-328) or TR11 (26-328) or TR1 (26-328) or TR2 (26-328) +final
______
Einstein's postulates; consequences for simultaneity, time dilation, length contraction, and clock synchronization; Lorentz transformation; relativistic effects and paradoxes; Minkowski diagrams; invariants and four-vectors; momentum, energy, and mass; particle collisions. Relativity and electricity; Coulomb's law; magnetic fields. Brief introduction to Newtonian cosmology. Introduction to some concepts of general relativity; principle of equivalence. The Schwarzchild metric; gravitational red shift; particle and light trajectories; geodesics; Shapiro delay.
T. Slatyer
Textbooks (Fall 2016)

8.04 Quantum Physics I
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: 8.03; 18.03 or 18.034
Units: 5-0-7
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR9.30-11 (4-237) Recitation: MW9 (26-328) or MW10 (26-328) +final
______
Experimental basis of quantum physics: photoelectric effect, Compton scattering, photons, Franck-Hertz experiment, the Bohr atom, electron diffraction, deBroglie waves, and wave-particle duality of matter and light. Introduction to wave mechanics: Schroedinger's equation, wave functions, wave packets, probability amplitudes, stationary states, the Heisenberg uncertainty principle, and zero-point energies. Solutions to Schroedinger's equation in one dimension: transmission and reflection at a barrier, barrier penetration, potential wells, the simple harmonic oscillator. Schroedinger's equation in three dimensions: central potentials and introduction to hydrogenic systems.
V. Vuletic
Textbooks (Fall 2016)

8.044 Statistical Physics I
______

Undergrad (Spring)
Prereq: 8.03, 18.03
Units: 5-0-7
URL: http://web.mit.edu/physics/subjects/index.html
______
Introduction to probability, statistical mechanics, and thermodynamics. Random variables, joint and conditional probability densities, and functions of a random variable. Concepts of macroscopic variables and thermodynamic equilibrium, fundamental assumption of statistical mechanics, microcanonical and canonical ensembles. First, second, and third laws of thermodynamics. Numerous examples illustrating a wide variety of physical phenomena such as magnetism, polyatomic gases, thermal radiation, electrons in solids, and noise in electronic devices. Concurrent enrollment in 8.04 is recommended.
Staff

8.05 Quantum Physics II
______

Undergrad (Fall)
Prereq: 8.04
Units: 5-0-7
Credit cannot also be received for8.S05
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW12.30-2 (6-120) Recitation: TR10 (26-322) or TR11 (26-322) or TR1 (26-314) or TR2 (26-314) +final
______
Together 8.05 and 8.06 cover quantum physics with applications drawn from modern physics. General formalism of quantum mechanics: states, operators, Dirac notation, representations, measurement theory. Harmonic oscillator: operator algebra, states. Quantum mechanics in three dimensions: central potentials and the radial equation, bound and scattering states, qualitative analysis of wavefunctions. Angular momentum: operators, commutator algebra, eigenvalues and eigenstates, spherical harmonics. Spin: Stern-Gerlach devices and measurements, nuclear magnetic resonance, spin and statistics. Addition of angular momentum: Clebsch-Gordan series and coefficients, spin systems, and allotropic forms of hydrogen.
A. Adams
Textbooks (Fall 2016)

8.06 Quantum Physics III
______

Undergrad (Spring)
Prereq: 8.05
Units: 5-0-7
URL: http://web.mit.edu/physics/subjects/index.html
______
Continuation of 8.05. Units: natural units, scales of microscopic phenomena, applications. Time-independent approximation methods: degenerate and nondegenerate perturbation theory, variational method, Born-Oppenheimer approximation, applications to atomic and molecular systems. The structure of one- and two-electron atoms: overview, spin-orbit and relativistic corrections, fine structure, variational approximation, screening, Zeeman and Stark effects. Charged particles in a magnetic field: Landau levels and integer quantum hall effect. Scattering: general principles, partial waves, review of one-dimension, low-energy approximations, resonance, Born approximation. Time-dependent perturbation theory. Students research and write a paper on a topic related to the content of 8.05 and 8.06.
Staff

8.07 Electromagnetism II
______

Undergrad (Fall)
Prereq: 8.03, 18.03
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW11-12.30 (6-120) +final
______
Survey of basic electromagnetic phenomena: electrostatics, magnetostatics; electromagnetic properties of matter. Time-dependent electromagnetic fields and Maxwell's equations. Electromagnetic waves, emission, absorption, and scattering of radiation. Relativistic electrodynamics and mechanics.
S. Hughes
Textbooks (Fall 2016)

8.08 Statistical Physics II
______

Undergrad (Spring)
Prereq: 8.044, 8.05
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
Probability distributions for classical and quantum systems. Microcanonical, canonical, and grand canonical partition-functions and associated thermodynamic potentials. Conditions of thermodynamic equilibrium for homogenous and heterogenous systems. Applications: non-interacting Bose and Fermi gases; mean field theories for real gases, binary mixtures, magnetic systems, polymer solutions; phase and reaction equilibria, critical phenomena. Fluctuations, correlation functions and susceptibilities, and Kubo formulae. Evolution of distribution functions: Boltzmann and Smoluchowski equations.
Staff

8.09 Classical Mechanics III
______

Undergrad (Fall)
(Subject meets with8.309)
Prereq: 8.223
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR9.30-11 (56-114) Recitation: F1 (26-328) or F2 (26-328) +final
______
Covers Lagrangian and Hamiltonian mechanics, systems with constraints, rigid body dynamics, vibrations, central forces, Hamilton-Jacobi theory, action-angle variables, perturbation theory, and continuous systems. Provides an introduction to ideal and viscous fluid mechanics, including turbulence, as well as an introduction to nonlinear dynamics, including chaos. Students taking graduate version complete different assignments.
I. Stewart
Textbooks (Fall 2016)

Undergraduate Laboratory and Special Project Subjects

8.13 Experimental Physics I
______

Undergrad (Fall, Spring) Institute Lab
Prereq: 8.04
Units: 0-6-12
URL: http://web.mit.edu/physics/subjects/index.html
Lab: MW9-12 (4-361) or MW2-5 (4-361) or TR9-12 (4-361) or TR2-5 (4-361)
______
G. Roland, J. Conrad, A. Levine, P. Zuccon
Textbooks (Fall 2016)

8.14 Experimental Physics II
______

Undergrad (Spring)
Prereq: 8.05, 8.13
Units: 0-6-12
URL: http://web.mit.edu/physics/subjects/index.html
______
Four fundamental laboratory experiments are carried out each term, covering most aspects of modern physics relating to names such as Rutherford, Franck-Hertz, Hall, Ramsauer, Doppler, Fraunhofer, Faraday, Mossbauer, Compton, and Stern-Gerlach. Stresses basic experimental techniques and data analysis, and written and oral presentation of experiment results. 8.14 requires knowledge of quantum mechanics at the 8.05 level.
G. Roland

8.18 Research Problems in Undergraduate Physics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Opportunity for undergraduates to engage in experimental or theoretical research under the supervision of a staff member. Specific approval required in each case.
Consult N. Mavalvala
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

8.19 Readings in Physics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Supervised reading and library work. Choice of material and allotment of time according to individual needs. For students who want to do work not provided for in the regular subjects. Specific approval required in each case.
Consult N. Mavalvala
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

Undergraduate Elective Subjects

8.20 Introduction to Special Relativity
______

Undergrad (IAP) Rest Elec in Sci & Tech
Prereq: Physics I (GIR), Calculus I (GIR)
Units: 2-0-7
URL: http://web.mit.edu/physics/subjects/index.html
______
Introduces the basic ideas and equations of Einstein's special theory of relativity. Topics include Lorentz transformations, length contraction and time dilation, four vectors, Lorentz invariants, relativistic energy and momentum, relativistic kinematics, Doppler shift, space-time diagrams, relativity paradoxes, and some concepts of general relativity. Intended for freshmen and sophomores. Not usable as a restricted elective by Physics majors. Credit cannot be received for 8.20 if credit for 8.033 is or has been received in the same or prior terms.
J. Formaggio

8.21 Physics of Energy
______

Not offered academic year 2016-2017Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Physics II (GIR), Calculus II (GIR), Chemistry (GIR)
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
Subject Cancelled Subject Cancelled
______
A comprehensive introduction to the fundamental physics of energy systems that emphasizes quantitative analysis. Focuses on the fundamental physical principles underlying energy processes and on the application of these principles to practical calculations. Applies mechanics and electromagnetism to energy systems; introduces and applies basic ideas from thermodynamics, quantum mechanics, and nuclear physics. Examines energy sources, conversion, transport, losses, storage, conservation, and end uses. Analyzes the physics of side effects, such as global warming and radiation hazards. Provides students with technical tools and perspective to evaluate energy choices quantitatively at both national policy and personal levels.
Staff

8.223 Classical Mechanics II
______

Undergrad (IAP)
Prereq: Physics I (GIR), Calculus II (GIR)
Units: 2-0-4
______
A broad, theoretical treatment of classical mechanics, useful in its own right for treating complex dynamical problems, but essential to understanding the foundations of quantum mechanics and statistical physics. Generalized coordinates, Lagrangian and Hamiltonian formulations, canonical transformations, and Poisson brackets. Applications to continuous media. The relativistic Lagrangian and Maxwell's equations.
Staff

8.224 Exploring Black Holes: General Relativity and Astrophysics
______

Not offered academic year 2017-2018Undergrad (Spring)
Prereq: 8.033 or 8.20
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Study of physical effects in the vicinity of a black hole as a basis for understanding general relativity, astrophysics, and elements of cosmology. Extension to current developments in theory and observation. Energy and momentum in flat space-time; the metric; curvature of space-time near rotating and nonrotating centers of attraction; trajectories and orbits of particles and light; elementary models of the Cosmos. Weekly meetings include an evening seminar and recitation. The last third of the term is reserved for collaborative research projects on topics such as the Global Positioning System, solar system tests of relativity, descending into a black hole, gravitational lensing, gravitational waves, Gravity Probe B, and more advanced models of the cosmos. Subject has online components that are open to selected MIT alumni. Alumni wishing to participate should contact Professor Bertschinger at edbert@mit.edu. Limited to 40.
E. Bertschinger

8.225[J] Einstein, Oppenheimer, Feynman: Physics in the 20th Century
______

Not offered academic year 2017-2018Undergrad (Spring) HASS Humanities
(Same subject asSTS.042[J])
Prereq: None
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Explores the changing roles of physics and physicists during the 20th century. Topics range from relativity theory and quantum mechanics to high-energy physics and cosmology. Examines the development of modern physics within shifting institutional, cultural, and political contexts, such as physics in Imperial Britain, Nazi Germany, US efforts during World War II, and physicists' roles during the Cold War. Enrollment limited.
D. I. Kaiser

8.226 Forty-three Orders of Magnitude
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 8.04, 8.044; or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Examines the widespread societal implications of current scientific discoveries in physics across forty-three orders of magnitude in length scale. Addresses topics ranging from climate change to nuclear nonproliferation. Students develop their ability to express concepts at a level accessible to the public and to present a well-reasoned argument on a topic that is a part of the national debate. Requires diverse writing assignments, including substantial papers. Enrollment limited.
J. Conrad

8.231 Physics of Solids I
______

Undergrad (Fall)
Prereq: 8.044,Coreq: 8.05
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR1-2.30 (4-261) Recitation: F1 (26-210)
______
Introduction to the basic concepts of the quantum theory of solids. Topics: periodic structure and symmetry of crystals; diffraction; reciprocal lattice; chemical bonding; lattice dynamics, phonons, thermal properties; free electron gas; model of metals; Bloch theorem and band structure, nearly free electron approximation; tight binding method; Fermi surface; semiconductors, electrons, holes, impurities; optical properties, excitons; and magnetism.
X-G. Wen
Textbooks (Fall 2016)

8.241 Introduction to Biological Physics
______

Undergrad (Spring)
Prereq: Physics II (GIR); 8.044 or 5.60
Units: 4-0-8
______
Introduces the main concepts of biological physics, with a focus on biophysical phenomena at the molecular and cellular scales. Presents the role of entropy and diffusive transport in living matter; challenges to life resulting from the highly viscous environment present at microscopic scales, including constraints on force, motion and transport within cells, tissues, and fluids; principles of how cellular machinery (e.g., molecular motors) can convert electro-chemical energy sources to mechanical forces and motion. Also covers polymer physics relevant to DNA and other biological polymers, including the study of configurations, fluctuations, rigidity, and entropic elasticity.
J. Gore, I. Cisse

8.251 String Theory for Undergraduates
______

Not offered academic year 2017-2018Undergrad (Spring)
Prereq: 8.033, 8.044, 8.05
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
Introduction to the main concepts of string theory, i.e. quantum mechanics of a relativistic string. Develops aspects of string theory and makes it accessible to students familiar with basic electromagnetism and statistical mechanics, including the study of D-branes and string thermodynamics.
H. Liu

8.276 Nuclear and Particle Physics
______

Not offered academic year 2017-2018Undergrad (Spring)
Prereq: 8.033, 8.04
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
Presents a modern view of the fundamental structure of matter. Starting from the Standard Model, which views leptons and quarks as basic building blocks of matter, establishes the properties and interactions of these particles. Explores applications of this phenomenology to both particle and nuclear physics. Emphasizes current topics in nuclear and particle physics research at MIT. Intended for students with a basic knowledge of relativity and quantum physics concepts.
M. Williams

8.277 Introduction to Particle Accelerators
______

Not offered academic year 2017-2018Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: 6.013 or 8.07; permission of instructor
Units arranged
Lecture: MW9.30-11 (8-205)
______
Principles of acceleration: beam properties; linear accelerators, synchrotrons, and storage rings. Accelerator technologies: radio frequency cavities, bending and focusing magnets, beam diagnostics. Particle beam optics and dynamics. Special topics: measures of accelerators performance in science, medicine and industry; synchrotron radiation sources; free electron lasers; high-energy colliders; and accelerators for radiation therapy. May be repeated for credit for a maximum of 12 units.
W. Barletta
No required or recommended textbooks

8.282[J] Introduction to Astronomy
______

Undergrad (Spring) Rest Elec in Sci & Tech
(Same subject as12.402[J])
Prereq: Physics I (GIR)
Units: 3-0-6
URL: http://web.mit.edu/physics/subjects/index.html
______
Quantitative introduction to physics of the solar system, stars, interstellar medium, the galaxy, and universe, as determined from a variety of astronomical observations and models. Topics: planets, planet formation; stars, the Sun, "normal" stars, star formation; stellar evolution, supernovae, compact objects (white dwarfs, neutron stars, and black holes), plusars, binary x-ray sources; star clusters, globular and open clusters; interstellar medium, gas, dust, magnetic fields, cosmic rays; distance ladder; galaxies, normal and active galaxies, jets; gravitational lensing; large scaling structure; Newtonian cosmology, dynamical expansion and thermal history of the universe; cosmic microwave background radiation; big bang nucleosynthesis. No prior knowledge of astronomy necessary. Not usable as a restricted elective by Physics majors.
Staff

8.284 Modern Astrophysics
______

Undergrad (Spring)
Prereq: 8.04,Coreq: 8.05
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Applications of physics (Newtonian, statistical, and quantum mechanics) to fundamental processes that occur in celestial objects. Includes main-sequence stars, collapsed stars (white dwarfs, neutron stars, and black holes), pulsars, supernovae, the interstellar medium, galaxies, and as time permits, active galaxies, quasars, and cosmology. Observational data discussed. No prior knowledge of astronomy is required.
Staff

8.286 The Early Universe
______

Not offered academic year 2017-2018Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: 18.03, Physics II (GIR)
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW11-12.30 (4-163)
______
Introduction to modern cosmology. First half deals with the development of the big bang theory from 1915 to 1980, and latter half with recent impact of particle theory. Topics: special relativity and the Doppler effect, Newtonian cosmological models, introduction to non-Euclidean spaces, thermal radiation and early history of the universe, big bang nucleosynthesis, introduction to grand unified theories and other recent developments in particle theory, baryogenesis, the inflationary universe model, and the evolution of galactic structure.
A. Guth
Textbooks (Fall 2016)

8.287[J] Observational Techniques of Optical Astronomy
______

Undergrad (Fall) Institute Lab
(Same subject as12.410[J])
Prereq: 8.282J, 12.402J, 12.409, or other introductory astronomy course;Coreq: 8.03
Units: 3-4-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MWF1 (54-517) Lab: TBA
______
Fundamental physical and optical principles used for astronomical measurements at visible wavelengths and practical methods of astronomical observations. Topics: astronomical coordinates, time, optics, telescopes, photon counting, signal-to-noise ratios, data analysis (including least-squares model fitting), limitations imposed by the Earth's atmosphere on optical observations, CCD detectors, photometry, spectroscopy, astrometry, and time variability. Project at Wallace Astrophysical Observatory. Written and oral project reports. Limited to 18; preference to Course 8 and Course 12 majors and minors.
R. Binzel, A. Bosh
Textbooks (Fall 2016)

8.290[J] Extrasolar Planets: Physics and Detection Techniques
______

Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject as12.425[J])
(Subject meets with12.625)
Prereq: 8.03, 18.03
Units: 2-1-9
Lecture: TR1.30-3 (54-824)
______
Presents basic principles of planet atmospheres and interiors applied to the study of extrasolar planets. Focuses on fundamental physical processes related to observable extrasolar planet properties. Provides a quantitative overview of detection techniques. Introduction to the feasibility of the search for Earth-like planets, biosignatures and habitable conditions on extrasolar planets. Students taking graduate version complete additional assignments.
S. Seager
No required or recommended textbooks

8.292[J] Fluid Physics
______

Undergrad (Spring)
(Same subject as12.330[J])
Prereq: 8.044, 5.60, or permission of instructor
Units: 3-0-9
______
A physics-based introduction to the properties of fluids and fluid systems, with examples drawn from a broad range of sciences, including atmospheric physics and astrophysics. Definitions of fluids and the notion of continuum. Equations of state and continuity, hydrostatics and conservation of momentum; ideal fluids and Euler's equation; viscosity and the Navier-Stokes equation. Energy considerations, fluid thermodynamics, and isentropic flow. Compressible versus incompressible and rotational versus irrotational flow; Bernoulli's theorem; steady flow, streamlines and potential flow. Circulation and vorticity. Kelvin's theorem. Boundary layers. Fluid waves and instabilities. Quantum fluids.
D. Cziczo

8.295 Practical Work Experience
(New)
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units: 0-1-0 [P/D/F]
TBA.
______
For Course 8 students participating in off-campus work experiences in physics. Before registering for this subject, students must have an employment offer from a company or organization and must identify a Physics supervisor. Upon completion of the work, student must submit a letter from the employer describing the work accomplished, along with a substantive final report from the student approved by the MIT supervisor. Subject to departmental approval. Consult departmental academic office.
Consult N. Mavalvala
No required or recommended textbooks

8.297 Physics of the 21st Century
______

Undergrad (Spring)
Not offered regularly; consult department
Prereq: 8.033, 8.044, 8.05, 8.13
Units: 4-0-8
______
Students study four topics in depth from themes of current interest over the course of the term. Topic examples include Bose-Einstein condensates, dark energy, neutrino interactions, superconductivity, photonics, semiconductor nanostructures, exoplanets, and space plasmas.
P. Fisher

8.298 Selected Topics in Physics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Presentation of topics of current interest, with content varying from year to year.
Consult I. Stewart
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

8.299 Physics Teaching
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
For qualified undergraduate students interested in gaining some experience in teaching. Laboratory, tutorial, or classroom teaching under the supervision of a faculty member. Students selected by interview.
Consult N. Mavalvala
No required or recommended textbooks

8.S10 Special Subject: Physics
______

Undergrad (IAP) Can be repeated for credit
Prereq: None
Units arranged
______
Opportunity for group study of subjects in physics not otherwise included in the curriculum.
A. Adams, K. Ellenbogen

8.S30 Special Subject: Physics
______

Undergrad (IAP)
Prereq: None
Units arranged
______
Opportunity for group study of subjects in physics not otherwise included in the curriculum.
A. Bernstein, J. Walsh

8.S50 Special Subject: Physics
______

Undergrad (Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
______
Opportunity for group study of subjects in physics not otherwise included in the curriculum.
E. Bertschinger

8.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Research opportunities in physics. For further information, contact the departmental UROP coordinator.
N. Mavalvala
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

8.THU Undergraduate Physics Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Program of research leading to the writing of an S.B. thesis; to be arranged by the student under approved supervision.
Information: N. Mavalvala
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|8.01-8.299 plus UROP and THU|8.300-8.999 plus THG|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 8: Physics
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Course 8: Physics
Fall 2016


Graduate Subjects

8.309 Classical Mechanics III
(New)
______

Graduate (Fall)
(Subject meets with8.09)
Prereq: None
Units: 4-0-8
Lecture: TR9.30-11 (56-114) Recitation: F1 (26-328) or F2 (26-328) +final
______
Covers Lagrangian and Hamiltonian mechanics, systems with constraints, rigid body dynamics, vibrations, central forces, Hamilton-Jacobi theory, action-angle variables, perturbation theory, and continuous systems. Provides an introduction to ideal and viscous fluid mechanics, including turbulence, as well as an introduction to nonlinear dynamics, including chaos. Students taking graduate version complete different assignments.
I. Stewart
No required or recommended textbooks

8.311 Electromagnetic Theory I
______

Graduate (Spring)
Prereq: 8.07
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
Basic principles of electromagnetism: experimental basis, electrostatics, magnetic fields of steady currents, motional emf and electromagnetic induction, Maxwell's equations, propagation and radiation of electromagnetic waves, electric and magnetic properties of matter, and conservation laws. Subject uses appropriate mathematics but emphasizes physical phenomena and principles.
Staff

8.321 Quantum Theory I
______

Graduate (Fall)
Prereq: 8.05
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW10-11.30 (4-265) Recitation: T10 (4-265) or F10 (4-261) +final
______
Textbooks (Fall 2016)

8.322 Quantum Theory II
______

Graduate (Spring)
Prereq: 8.07, 8.321
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
A two-term subject on quantum theory, stressing principles: uncertainty relation, observables, eigenstates, eigenvalues, probabilities of the results of measurement, transformation theory, equations of motion, and constants of motion. Symmetry in quantum mechanics, representations of symmetry groups. Variational and perturbation approximations. Systems of identical particles and applications. Time-dependent perturbation theory. Scattering theory: phase shifts, Born approximation. The quantum theory of radiation. Second quantization and many-body theory. Relativistic quantum mechanics of one electron.
R. Jackiw

8.323 Relativistic Quantum Field Theory I
______

Graduate (Spring)
Prereq: 8.321
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
A one-term self-contained subject in quantum field theory. Concepts and basic techniques are developed through applications in elementary particle physics, and condensed matter physics. Topics: classical field theory, symmetries, and Noether's theorem. Quantization of scalar fields, spin fields, and Gauge bosons. Feynman graphs, analytic properties of amplitudes and unitarity of the S-matrix. Calculations in quantum electrodynamics (QED). Introduction to renormalization.
Staff

8.324 Relativistic Quantum Field Theory II
______

Graduate (Fall)
Prereq: 8.322, 8.323
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW EVE (4.30-6 PM) (32-144) Recitation: F10 (26-414)
______
The second term of the quantum field theory sequence. Develops in depth some of the topics discussed in 8.323 and introduces some advanced material. Topics: perturbation theory and Feynman diagrams, scattering theory, Quantum Electrodynamics, one loop renormalization, quantization of non-abelian gauge theories, the Standard Model of particle physics, other topics.
H. Liu
Textbooks (Fall 2016)

8.325 Relativistic Quantum Field Theory III
______

Graduate (Spring)
Prereq: 8.324
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
The third and last term of the quantum field theory sequence. Its aim is the proper theoretical discussion of the physics of the standard model. Topics: quantum chromodynamics; Higgs phenomenon and a description of the standard model; deep-inelastic scattering and structure functions; basics of lattice gauge theory; operator products and effective theories; detailed structure of the standard model; spontaneously broken gauge theory and its quantization; instantons and theta-vacua; topological defects; introduction to supersymmetry.
Staff

8.333 Statistical Mechanics I
______

Graduate (Fall)
Prereq: 8.044, 8.05
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW2.30-4 (4-163) Recitation: F2.30-4 (4-163) +final
______
Textbooks (Fall 2016)

8.334 Statistical Mechanics II
______

Graduate (Spring)
Prereq: 8.333
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
A two-term subject on statistical mechanics. Basic principles are examined in 8.333: the laws of thermodynamics and the concepts of temperature, work, heat, and entropy. Postulates of classical statistical mechanics, microcanonical, canonical, and grand canonical distributions; applications to lattice vibrations, ideal gas, photon gas. Quantum statistical mechanics; Fermi and Bose systems. Interacting systems: cluster expansions, van der Waal's gas, and mean-field theory. Topics from modern statistical mechanics are explored in 8.334: the hydrodynamic limit and classical field theories. Phase transitions and broken symmetries: universality, correlation functions, and scaling theory. The renormalization approach to collective phenomena. Dynamic critical behavior. Random systems.
8.333: M. Kardar; 8.334: Staff

8.351[J] Classical Mechanics: A Computational Approach
______

Graduate (Fall)
(Same subject as6.946[J],12.620[J])
Prereq: Physics I (GIR), 18.03, permission of instructor
Units: 3-3-6
Credit cannot also be received for12.008
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MWF11 (54-819) Lab: W EVE (7-10 PM) (14-0637)
______
Classical mechanics in a computational framework, Lagrangian formulation, action, variational principles, and Hamilton's principle. Conserved quantities, Hamiltonian formulation, surfaces of section, chaos, and Liouville's theorem. Poincaré integral invariants, Poincaré-Birkhoff and KAM theorems. Invariant curves and cantori. Nonlinear resonances, resonance overlap and transition to chaos. Symplectic integration. Adiabatic invariants. Applications to simple physical systems and solar system dynamics. Extensive use of computation to capture methods, for simulation, and for symbolic analysis. Programming experience required. Students taking the graduate version complete additional assignments.
J. Wisdom, G. J. Sussman
Textbooks (Fall 2016)

8.361 Quantum Theory of Many-Particle Systems
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 8.322, 8.333
Units: 3-0-9
______
Introduces general many-body theory applicable to low temperature, nuclear, and solid-state physics. Reviews occupation number representation and classical Mayer expansion. Perturbation theory: diagrammatic expansions and linked-cluster theorem for zero or finite temperature systems of fermions or bosons. Green's functions: analytic properties, equations of motion, relation to observables, approximations, linear response theory, and random phase approximation. Superconductivity: electron-phonon interaction, instability of normal state, BCS ground state, perturbation theory.
Staff

8.370[J] Quantum Computation
______

Graduate (Fall)
(Same subject as2.111[J],18.435[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (4-370) +final
______
Provides an introduction to the theory and practice of quantum computation. Topics covered: physics of information processing; quantum algorithms including the factoring algorithm and Grover's search algorithm; quantum error correction; quantum communication and cryptography. Knowledge of quantum mechanics helpful but not required.
I. Chuang, E. Farhi, S. Lloyd, P. Shor
Textbooks (Fall 2016)

8.371[J] Quantum Information Science
______

Graduate (Spring)
(Same subject as6.443[J],18.436[J])
Prereq: 18.435
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Examines quantum computation and quantum information. Topics include quantum circuits, the quantum Fourier transform and search algorithms, the quantum operations formalism, quantum error correction, Calderbank-Shor-Steane and stabilizer codes, fault tolerant quantum computation, quantum data compression, quantum entanglement, capacity of quantum channels, and quantum cryptography and the proof of its security. Prior knowledge of quantum mechanics required.
I. Chuang

8.381, 8.382 Selected Topics in Theoretical Physics
______

Graduate (Fall, Spring)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Topics of current interest in theoretical physics, varying from year to year. Subject not routinely offered; given when sufficient interest is indicated.
Staff

8.391 Pre-Thesis Research
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

8.392 Pre-Thesis Research
______

Graduate (Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Advanced problems in any area of experimental or theoretical physics, with assigned reading and consultations.
Staff
No textbook information available

8.395[J] Teaching College-Level Science and Engineering
______

Graduate (Fall)
(Same subject as1.95[J],5.95[J],7.59[J],18.094[J])
(Subject meets with2.978)
Prereq: None
Units: 2-0-2 [P/D/F]
URL: https://wikis.mit.edu/confluence/pages/viewpage.action?pageId=110876412
Lecture: R9-11 (4-149)
______
Participatory seminar focuses on the knowledge and skills necessary for teaching science and engineering in higher education. Topics include theories of adult learning; course development; promoting active learning, problemsolving, and critical thinking in students; communicating with a diverse student body; using educational technology to further learning; lecturing; creating effective tests and assignments; and assessment and evaluation. Students research and present a relevant topic of particular interest. Appropriate for both novices and those with teaching experience.
J. Rankin
No required or recommended textbooks

8.398 Selected Topics in Graduate Physics
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: R9-11 (4-265)
______
Presentation of topics of current interest with content varying from year to year.
Consult N. Mavalvala
No required or recommended textbooks

8.399 Physics Teaching
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
For qualified graduate students interested in gaining some experience in teaching. Laboratory, tutorial, or classroom teaching under the supervision of a faculty member. Students selected by interview.
Consult C. Paus
No required or recommended textbooks

Physics of Atoms, Radiation, Solids, Fluids, and Plasmas

8.421 Atomic and Optical Physics I
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 8.05
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
The first of a two-term subject sequence that provides the foundations for contemporary research in selected areas of atomic and optical phsyics. The interaction of radiation with atoms: resonance; absorption, stimulated and spontaneous emission; methods of resonance, dressed atom formalism, masers and lasers, cavity quantum electrodynamics; structure of simple atoms, behavior in very strong fields; fundamental tests: time reversal, parity violations, Bell's inequalities; and experimental methods.
Staff

8.422 Atomic and Optical Physics II
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 8.05
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
The second of a two-term subject sequence that provides the foundations for contemporary research in selected areas of atomic and optical physics. Non-classical states of light- squeezed states; multi-photon processes, Raman scattering; coherence- level crossings, quantum beats, double resonance, superradiance; trapping and cooling- light forces, laser cooling, atom optics, spectroscopy of trapped atoms and ions; atomic interactions- classical collisions, quantum scattering theory, ultracold collisions; and experimental methods.
Staff

8.431[J] Nonlinear Optics
______

Graduate (Spring)
(Same subject as6.634[J])
Prereq: 6.013 or 8.07
Units: 3-0-9
______
Techniques of nonlinear optics with emphasis on fundamentals for research and engineering in optics, photonics, and spectroscopy. Electro optic modulators, harmonic generation, and frequency conversion devices. Nonlinear effects in optical fibers including self-phase modulation, nonlinear wave propagation, and solitons. Interaction of light with matter, laser operation, density matrix techniques, nonlinear spectroscopies, and femtosecond optics.
J. G. Fujimoto

8.481, 8.482 Selected Topics in Physics of Atoms and Radiation
______

Graduate (Fall, Spring)
Not offered regularly; consult department
Prereq: 8.321
Units: 3-0-9
______
Presentation of topics of current interest, with content varying from year to year. Subject not routinely offered; given when sufficient interest is indicated.
Staff

8.511 Theory of Solids I
______

Graduate (Fall)
Prereq: 8.231
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW1-2.30 (4-153)
______
First term of a theoretical treatment of the physics of solids. Concept of elementary excitations. Symmetry- translational, rotational, and time-reversal invariances- theory of representations. Energy bands- APW, OPW, pseudopotential and LCAO schemes. Survey of electronic structure of metals, semimetals, semiconductors, and insulators, excitons, critical points, response functions, and interactions in the electron gas.
L. Levitov
Textbooks (Fall 2016)

8.512 Theory of Solids II
______

Graduate (Spring)
Prereq: 8.511
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Second term of a theoretical treatment of the physics of solids. Interacting electron gas: many-body formulation, Feynman diagrams, random phase approximation and beyond. General theory of linear response: dielectric function; sum rules; plasmons; optical properties; applications to semiconductors, metals, and insulators. Transport properties: non-interacting electron gas with impurities, diffusons. Quantum Hall effect: integral and fractional. Electron-phonon interaction: general theory, applications to metals, semiconductors and insulators, polarons, and field-theory description. Superconductivity: experimental observations, phenomenological theories, and BCS theory.
Staff

8.513 Many-Body Theory for Condensed Matter Systems
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 8.05, 8.08, 8.033, 8.231J
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Concepts and physical pictures behind various phenomena that appear in interacting many-body systems. Visualization occurs through concentration on path integral, mean-field theories and semiclassical picture of fluctuations around mean-field state. Topics covered: interacting boson/fermion systems, Fermi liquid theory and bosonization, symmetry breaking and nonlinear sigma-model, quantum gauge theory, quantum Hall theory, mean-field theory of spin liquids and quantum order, string-net condensation and emergence of light and fermions.
L. Levitov

8.514 Strongly Correlated Systems in Condensed Matter Physics
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 8.322, 8.333
Units: 3-0-9
______
Study of condensed matter systems where interactions between electrons play an important role. Topics vary depending on lecturer but may include low-dimension magnetic and electronic systems, disorder and quantum transport, magnetic impurities (the Kondo problem), quantum spin systems, the Hubbard model and high-temperature superconductors. Topics are chosen to illustrate the application of diagrammatic techniques, field-theory approaches, and renormalization group methods in condensed matter physics.
X. Wen

8.581, 8.582 Selected Topics in Condensed Matter Physics
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Presentation of topics of current interest, with contents varying from year to year. Subject not routinely offered; given when sufficient interest is indicated.
Staff

8.590[J] Topics in Biophysics and Physical Biology
______

Graduate (Fall)
(Same subject as7.74[J],20.416[J])
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: F1-2.30 (56-167)
______
Provides broad exposure to research in biophysics and physical biology, with emphasis on the critical evaluation of scientific literature. Weekly meetings include in-depth discussion of scientific literature led by distinct faculty on active research topics. Each session also includes brief discussion of non-research topics including effective presentation skills, writing papers and fellowship proposals, choosing scientific and technical research topics, time management, and scientific ethics.
I. Cisse, N. Fakhri, M. Guo
No required or recommended textbooks

8.591[J] Systems Biology
______

Graduate (Fall)
(Same subject as7.81[J])
(Subject meets with7.32)
Prereq: 18.03, 18.05; or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR1-2.30 (4-159) Recitation: TBA +final
______
Introduction to cellular and population-level systems biology with an emphasis on synthetic biology, modeling of genetic networks, cell-cell interactions, and evolutionary dynamics. Cellular systems include genetic switches and oscillators, network motifs, genetic network evolution, and cellular decision-making. Population-level systems include models of pattern formation, cell-cell communication, and evolutionary systems biology. Students taking graduate version explore the subject in more depth.
J. Gore
Textbooks (Fall 2016)

8.592[J] Statistical Physics in Biology
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject asHST.452[J])
Prereq: 8.333 or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
A survey of problems at the interface of statistical physics and modern biology: bioinformatic methods for extracting information content of DNA; gene finding, sequence comparison, phylogenetic trees. Physical interactions responsible for structure of biopolymers; DNA double helix, secondary structure of RNA, elements of protein folding. Considerations of force, motion, and packaging; protein motors, membranes. Collective behavior of biological elements; cellular networks, neural networks, and evolution.
M. Kardar, L. Mirny

8.593[J] Biological Physics
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject asHST.450[J])
Prereq: 8.044 recommended but not necessary
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
Designed to provide seniors and first-year graduate students with a quantitative, analytical understanding of selected biological phenomena. Topics include experimental and theoretical basis for the phase boundaries and equation of state of concentrated protein solutions, with application to diseases such as sickle cell anemia and cataract. Protein-ligand binding and linkage and the theory of allosteric regulation of protein function, with application to proteins as stores as transporters in respiration, enzymes in metabolic pathways, membrane receptors, regulators of gene expression, and self-assembling scaffolds. The physics of locomotion and chemoreception in bacteria and the biophysics of vision, including the theory of transparency of the eye, molecular basis of photo reception, and the detection of light as a signal-to-noise discrimination.
G. Benedek

8.613[J] Introduction to Plasma Physics I
______

Graduate (Fall)
(Same subject as22.611[J])
Prereq: 6.013 or 8.07; 18.04 orCoreq: 18.075
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR11-12.30 (NW16-213)
______
Introduces plasma phenomena relevant to energy generation by controlled thermonuclear fusion and to astrophysics. Elementary plasma concepts, plasma characterization. Motion of charged particles in magnetic fields. Coulomb collisions, relaxation times, transport processes. Two-fluid hydrodynamic and MHD descriptions. Plasma confinement by magnetic fields, simple equilibrium and stability analysis. Wave propagation in a magnetic field; application to RF plasma heating. Introduction to kinetic theory; Vlasov, Boltzmann and Fokker-Planck equations; relation of fluid and kinetic descriptions. Electron and ion acoustic plasma waves, Landau damping.
A. White
Textbooks (Fall 2016)

8.614[J] Introduction to Plasma Physics II
______

Graduate (Spring)
(Same subject as22.612[J])
Prereq: 6.651J, 8.613J, or 22.611J
Units: 3-0-9
______
Linear waves and instabilities in magnetized plasma; solutions of Vlasov-Maxwell equations in homogeneous and inhomogeneous plasmas; conservation principles for energy and momentum; quasi-linear theory and nonlinear stabilization; solitons and coherent nonlinear phenomena; collisions and discrete particle effects; fluctuations in a stable plasma; Fokker-Planck equation and transport phenomena. A subject description tailored to fit the background and interests of the attending students distributed shortly before and at the beginning of the subject.
Staff

8.624 Plasma Waves
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 8.613J
Units: 3-0-9
______
Comprehensive theory of electromagnetic waves in a magnetized plasma. Wave propagation in cold and hot plasmas. Energy flow. Absorption by Landau and cyclotron damping and by transit time magnetic pumping (TTMP). Wave propagation in inhomogeneous plasma: accessibility, WKB theory, mode conversion, connection formulae, and Budden tunneling. Applications to RF plasma heating, wave propagation in the ionosphere and laser-plasma interactions. Wave propagation in toroidal plasmas, and applications to ion cyclotron (ICRF), electron cyclotron (ECRH), and lower hybrid (LHH) wave heating. Quasi-linear theory and applications to RF current drive in tokamaks. Extensive discussion of relevant experimental observations.
M. Porkolab

8.641 Physics of High-Energy Plasmas I
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 8.613J
Units: 3-0-9
______

8.642 Physics of High-Energy Plasmas II
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 8.613
Units: 3-0-9
______
Basic concepts of plasmas, with temperatures of thermonuclear interest, relevant to fusion research and astrophysics. Microscopic transport processes due to interparticle collisions and collective modes (e.g., microinstabilities). Relevant macroscopic transport coefficients (electrical resistivity, thermal conductivities, particle "diffusion"). Runaway and slide-away regimes. Magnetic reconnection processes and their relevance to experimental observations. Radiation emission from inhomogeneous plasmas. Conditions for thermonuclear burning and ignition (D-T and "advanced" fusion reactions, plasmas with polarized nuclei). Role of "impurity" nuclei. "Finite-β" (pressure) regimes and ballooning modes. Convective modes in configuration and velocity space. Trapped particle regimes. Nonlinear and explosive instabilities. Interaction of positive and negative energy modes. Each subject can be taken independently.
Staff

8.681, 8.682 Selected Topics in Fluid and Plasma Physics
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: 8.613J
Units: 3-0-9
______
Presentation of topics of current interest, with content varying from year to year. Subject not routinely offered; given when interest is indicated.
Consult M. Porkolab

Nuclear and Particle Physics

8.701 Introduction to Nuclear and Particle Physics
______

Graduate (Fall)
Prereq: None.Coreq: 8.321
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR1.30-3 (26-414)
______
The phenomenology and experimental foundations of particle and nuclear physics; the fundamental forces and particles, composites. Interactions of particles with matter, and detectors. SU(2), SU(3), models of mesons and baryons. QED, weak interactions, parity violation, lepton-nucleon scattering, and structure functions. QCD, gluon field and color. W and Z fields, electro-weak unification, the CKM matrix. Nucleon-nucleon interactions, properties of nuclei, single- and collective- particle models. Electron and hadron interactions with nuclei. Relativistic heavy ion collisions, and transition to quark-gluon plasma.
J. Formaggio
Textbooks (Fall 2016)

8.711 Nuclear Physics
______

Graduate (Spring)
Prereq: 8.321, 8.701
Units: 4-0-8
______
Modern, advanced study in the experimental foundations and theoretical understanding of the structure of nuclei, beginning with the two- and three-nucleon problems. Basic nuclear properties, collective and single-particle motion, giant resonances, mean field models, interacting boson model. Nuclei far from stability, nuclear astrophysics, big-bang and stellar nucleosynthesis. Electron scattering: nucleon momentum distributions, scaling, olarization observables. Parity-violating electron scattering. Neutrino physics. Current results in relativistic heavy ion physics and hadronic physics. Frontiers and future facilities.
J. Matthews

8.712 Advanced Topics in Nuclear Physics
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: 8.711 or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Subject for experimentalists and theorists with rotation of the following topics: (1) Nuclear chromodynamics-- introduction to QCD, structure of nucleons, lattice QCD, phases of hadronic matter; and relativistic heavy ion collisions. (2) Medium-energy physics-- nuclear and nucleon structure and dynamics studied with medium- and high-energy probes (neutrinos, photons, electrons, nucleons, pions, and kaons). Studies of weak and strong interactions.
Staff

8.781, 8.782 Selected Topics in Nuclear Theory
______

Graduate (Fall, Spring)
Not offered regularly; consult department
Prereq: 8.323
Units: 3-0-9
______
Presents topics of current interest in nuclear structure and reaction theory, with content varying from year to year. Subject not routinely offered; given when sufficient interest is indicated.
Consult E. Farhi

8.811 Particle Physics
______

Graduate (Fall)
Prereq: 8.701
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MW1.30-3 Recitation: F1.30
______
Modern review of particles, interactions, and recent experiments. Experimental and analytical methods. QED, electroweak theory, and the Standard Model as tested in recent key experiments at ee and pp colliders. Mass generation, W, Z, and Higgs physics. Weak decays of mesons, including heavy flavors with QCD corrections. Mixing phenomena for K, D, B mesons and neutrinos. CP violation with results from B-factories. Future physics expectations: Higgs, SUSY, sub-structure as addressed by new experiments at the LHC collider.
L. Winslow
Textbooks (Fall 2016)

8.812 Graduate Experimental Physics
______

Not offered academic year 2016-2017Graduate (IAP)
Prereq: 8.701
Units: 1-8-3
______
Provides practical experience in particle detection with verification by (Feynman) calculations. Students perform three experiments; at least one requires actual construction following design. Topics include Compton effect, Fermi constant in muon decay, particle identification by time-of-flight, Cerenkov light, calorimeter response, tunnel effect in radioactive decays, angular distribution of cosmic rays, scattering, gamma-gamma nuclear correlations, and modern particle localization.
U. Becker

8.821 String Theory
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 8.324
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
An introduction to string theory. Basics of conformal field theory; light-cone and covariant quantization of the relativistic bosonic string; quantization and spectrum of supersymmetric 10-dimensional string theories; T-duality and D-branes; toroidal compactification and orbifolds; 11-dimensional supergravity and M-theory.
H. Liu

8.831[J] Supersymmetric Quantum Field Theories
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
(Same subject as18.396[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Topics selected from the following: SUSY algebras and their particle representations; Weyl and Majorana spinors; Lagrangians of basic four-dimensional SUSY theories, both rigid SUSY and supergravity; supermultiplets of fields and superspace methods; renormalization properties, and the non-renormalization theorem; spontaneous breakdown of SUSY; and phenomenological SUSY theories. Some prior knowledge of Noether's theorem, derivation and use of Feynman rules, l-loop renormalization, and gauge theories is essential.
D. Z. Freedman

8.841 Electroweak Interactions
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 8.324
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
An introduction to the standard model of electroweak interactions and beyond; neutrino interactions and masses; the CKM matrix; lepton scattering off of necleons and nuclei; the search for the Higgs boson; supersymmetric extension of the standard model. Topics vary with instructor.
Staff

8.851 Effective Field Theory
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 8.324
Units: 3-0-9
Credit cannot also be received for8.S851
URL: http://web.mit.edu/physics/subjects/index.html
______
Covers the framework and tools of effective field theory, including: identifying degrees of freedom and symmetries; power counting expansions (dimensional and otherwise); field redefinitions, bottom-up and top-down effective theories; fine-tuned effective theories; matching and Wilson coefficients; reparameterization invariance; and advanced renormalization group techniques. Main examples are taken from particle and nuclear physics, including the Soft-Collinear Effective Theory.
I. Stewart

8.861 Advanced Topics in Superfluidity
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 8.324
Units: 3-0-9
______
Basic pairing theory, effective field theory and spontaneous symmetry breaking; well-established applications to liquid helium 3 as a warm-up; research will be explored including anisotropic superconductivity in heavy fermion systems and cuprates; color superconductivity in high-density QCD; and pairing in fermion systems with mismatched Fermi surfaces, including ultracold atom systems. Additional ideas needed to discuss the fractional quantum Hall effect will be reviewed, emphasizing its connection to conventional superfluidity, and pointing toward aspects of anyon behavior potentially relevant for quantum information processing.
Staff

8.871 Selected Topics in Theoretical Particle Physics
______

Not offered academic year 2016-2017Graduate (Fall, Spring) Can be repeated for credit
Prereq: 8.323
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______

8.872 Selected Topics in Theoretical Particle Physics
______

Not offered academic year 2016-2017Graduate (Fall, Spring) Can be repeated for credit
Prereq: 8.323
Units: 3-0-9
______
Presents topics of current interest in theoretical particle physics, with content varying from year to year. Subject not routinely offered; given when sufficient interest is indicated.
Staff

8.881, 8.882 Selected Topics in Experimental Particle Physics
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: 8.811
Units: 3-0-9
______
Presents topics of current interest in experimental particle physics, with content varying from year to year. Subject not routinely offered; given when sufficient interest is indicated.
Staff

Space Physics and Astrophysics

8.901 Astrophysics I
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Size and time scales. Historical astronomy. Astronomical instrumentation. Stars: spectra and classification. Stellar structure equations and survey of stellar evolution. Stellar oscillations. Degenerate and collapsed stars; radio pulsars. Interacting binary systems; accretion disks, x-ray sources. Gravitational lenses; dark matter. Interstellar medium: HII regions, supernova remnants, molecular clouds, dust; radiative transfer; Jeans' mass; star formation. High-energy astrophysics: Compton scattering, bremsstrahlung, synchrotron radiation, cosmic rays. Galactic stellar distributions and populations; Oort constants; Oort limit; and globular clusters.
Staff

8.902 Astrophysics II
______

Graduate (Fall)
Prereq: 8.901
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR11-12.30 (4-261) +final
______
Galactic dynamics: potential theory, orbits, collisionless Boltzmann equation, etc. Galaxy interactions. Groups and clusters; dark matter. Intergalactic medium; x-ray clusters. Active galactic nuclei: unified models, black hole accretion, radio and optical jets, etc. Homogeneity and isotropy, redshift, galaxy distance ladder. Newtonian cosmology. Roberston-Walker models and cosmography. Early universe, primordial nucleosynthesis, recombination. Cosmic microwave background radiation. Large-scale structure, galaxy formation.
M. Vogelsberger
Textbooks (Fall 2016)

8.913 Plasma Astrophysics I
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
______
Staff

8.914 Plasma Astrophysics II
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
For students interested in space physics, astrophysics, and plasma physics in general. Magnetospheres of rotating magnetized planets, ordinary stars, neutron stars, and black holes. Pulsar models: processes for slowing down, particle acceleration, and radiation emission; accreting plasmas and x-ray stars; stellar winds; heliosphere and solar wind- relevant magnetic field configuration, measured particle distribution in velocity space and induced collective modes; stability of the current sheet and collisionless processes for magnetic reconnection; theory of collisionless shocks; solitons; Ferroaro-Rosenbluth sheet; solar flare models; heating processes of the solar corona; Earth's magnetosphere (auroral phenomena and their interpretation, bowshock, magnetotail, trapped particle effects); relationship between gravitational (galactic) plasmas and electromagnetic plasmas. 8.913 deals with heliospheric, 8.914 with extra-heliospheric plasmas.
B. Coppi

8.921 Stellar Structure and Evolution
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Observable stellar characteristics; overview of observational information. Principles underlying calculations of stellar structure. Physical processes in stellar interiors; properties of matter and radiation; radiative, conductive, and convective heat transport; nuclear energy generation; nucleosynthesis; and neutrino emission. Protostars; the main sequence, and the solar neutrino flux; advanced evolutionary stages; variable stars; planetary nebulae, supernovae, white dwarfs, and neutron stars; close binary systems; and abundance of chemical elements.
Staff

8.942 Cosmology
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Thermal backgrounds in space. Cosmological principle and its consequences: Newtonian cosmology and types of "universes"; survey of relativistic cosmology; horizons. Overview of evolution in cosmology; radiation and element synthesis; physical models of the "early stages." Formation of large-scale structure to variability of physical laws. First and last states. Some knowledge of relativity expected. 8.962 recommended though not required.
M. Tegmark

8.952 Particle Physics of the Early Universe
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 8.323,Coreq: 8.324
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
______
Basics of general relativity, standard big bang cosmology, thermodynamics of the early universe, cosmic background radiation, primordial nucleosynthesis, basics of the standard model of particle physics, electroweak and QCD phase transition, basics of group theory, grand unified theories, baryon asymmetry, monopoles, cosmic strings, domain walls, axions, inflationary universe, and structure formation.
A. Guth

8.962 General Relativity
______

Graduate (Spring)
Prereq: 18.03, 18.06, 8.07
Units: 4-0-8
URL: http://web.mit.edu/physics/subjects/index.html
______
The basic principles of Einstein's general theory of relativity, differential geometry, experimental tests of general relativity, black holes, and cosmology.
Staff

8.971 Astrophysics Seminar
______

Not offered academic year 2016-2017Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
URL: http://web.mit.edu/physics/subjects/index.html
______
Advanced seminar on current topics, with a different focus each term. Typical topics: astronomical instrumentation, numerical and statistical methods in astrophysics, gravitational lenses, neutron stars and pulsars.
Consult D. Chakrabarty

8.972 Astrophysics Seminar
______

Not offered academic year 2016-2017Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
URL: http://web.mit.edu/physics/subjects/index.html
______
Advanced seminar on current topics, with a different focus each term. Typical topics: gravitational lenses, active galactic nuclei, neutron stars and pulsars, galaxy formation, supernovae and supernova remnants, brown dwarfs, and extrasolar planetary systems. The presenter at each session is selected by drawing names from a hat containing those of all attendees. Offered if sufficient interest is indicated.
Consult D. Chakrabarty

8.981, 8.982 Selected Topics in Astrophysics
______

Not offered academic year 2017-2018Graduate (Spring) Can be repeated for credit
Prereq: Permission of Instructor
Units: 3-0-9 [P/D/F]
______
Topics of current interest, varying from year to year. Subject not routinely offered; given when sufficient interest is indicated.
Consult D. Chakrabarty

8.995 Practical Work Experience
(New)
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
For Course 8 students participating in off-campus work experiences in physics. Before registering for this subject, students must have an employment offer from a company or organization, must identify a Physics supervisor, and must receive prior approval from the Physics Department. Upon completion of the work, student must submit a letter from the employer describing the work accomplished, along with a substantive final report from the student approved by the MIT supervisor. Consult departmental academic office.
Consult N. Mavalvala
No required or recommended textbooks

8.S301 Special Subject: Physics
______

Graduate (Spring)
Prereq: Permission of instructor
Units arranged
______
Covers topics in Physics that are not offered in the regular curriculum. Limited enrollment; preference to Physics graduate students.
A. Lightman

8.S421 Special Subject: Physics
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Opportunity for group study of subjects in physics not otherwise included in the curriculum.
W. Ketterle
No required or recommended textbooks

8.THG Graduate Physics Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of an SM, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member.
Consult I. Stewart
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


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Produced: 29-SEP-2016 06:37 AMFall 2016 Course 9: Brain and Cognitive Sciences
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Course 9: Brain and Cognitive Sciences
Fall 2016


9.00 Introduction to Psychological Science
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 4-0-8
______
A survey of the scientific study of human nature, including how the mind works, and how the brain supports the mind. Topics include the mental and neural bases of perception, emotion, learning, memory, cognition, child development, personality, psychopathology, and social interaction. Consideration of how such knowledge relates to debates about nature and nurture, free will, consciousness, human differences, self, and society.
J. D. Gabrieli

9.01 Introduction to Neuroscience
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Physics II (GIR) or permission of instructor
Units: 4-0-8
Lecture: MW1-2.30 (46-3002) Recitation: W EVE (7 PM) (56-162) or R EVE (7 PM) (56-162) or F11 (46-1015) or F2 (46-1015) +final
______
Introduction to the mammalian nervous system, with emphasis on the structure and function of the human brain. Topics include the function of nerve cells, sensory systems, control of movement, learning and memory, and diseases of the brain.
M. Bear
Textbooks (Fall 2016)

9.011 Systems Neuroscience
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 6-0-12
Lecture: MWF2-4 (46-3015) +final
______
Survey of brain and behavioral studies. Examines principles underlying the structure and function of the nervous system, with a focus on systems approaches. Topics include development of the nervous system and its connections, sensory systems of the brain, the motor system, higher cortical functions, and behavioral and cellular analyses of learning and memory. Preference to first-year graduate students in BCS.
M. Wilson, E. K. Miller
No required or recommended textbooks

9.012 Cognitive Science
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 6-0-12
______
Intensive survey of cognitive science. Topics include visual perception, language, memory, cognitive architecture, learning, reasoning, decision-making, and cognitive development. Topics covered from behavioral, computational, and neural perspectives.
E. Gibson, P. Sinha, J. Tenenbaum

9.013[J] Molecular and Cellular Neuroscience Core II
______

Graduate (Spring)
(Same subject as7.68[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Survey and primary literature review of major areas in molecular and cellular neurobiology. Covers genetic neurotrophin signaling, adult neurogenesis, G-protein coupled receptor signaling, glia function, epigenetics, neuronal and homeostatic plasticity, neuromodulators of circuit function, and neurological/psychiatric disease mechanisms. Includes lectures and exams, and involves presentation and discussion of primary literature. 9.015 recommended, though the core subjects can be taken in any sequence.
G. Feng, L.-H. Tsai

9.014 Quantitative Methods and Computational Models in Neurosciences
(New)
______

Graduate (Fall)
Prereq: None
Units: 3-1-8
Lecture: W11,F10-12 (46-3015) Lab: M11 (46-3015)
______
Provides theoretical background and practical skills needed to analyze and model neurobiological observations at the molecular, systems and cognitive levels. Develops an intuitive understanding of mathematical tools and computational techniques which students apply to analyze, visualize and model research data using MATLAB programming. Topics include linear systems and operations, dimensionality reduction (e.g., PCA), Bayesian approaches, descriptive and generative models, classification and clustering, and dynamical systems.
M. Jazayeri, D. Zysman
No required or recommended textbooks

9.015[J] Molecular and Cellular Neuroscience Core I
______

Graduate (Fall)
(Same subject as7.65[J])
Prereq: None
Units: 3-0-9
Lecture: TR1-2.30 (46-4062)
______
Survey and primary literature review of major topic areas in molecular and cellular neurobiology. Covers neurogenomics, nervous system formation, axonal pathfinding, cytoskeletal regulation, synapse formation, neurotransmitter release, and cellular neurophysiology. Includes lectures and weekly paper write-ups, together with student presentations and discussion of primary literature. A final two-page research write-up is also due at the end of the term.
J. T. Littleton, H. Sive, F. Gertler
No required or recommended textbooks

9.04 Sensory Systems
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 9.01 or permission of instructor
Units: 3-0-9
______
Examines the neural bases of sensory perception. Focuses on physiological and anatomical studies of the mammalian nervous system as well as behavioral studies of animals and humans. Topics include visual pattern, color and depth perception, auditory responses and sound localization, olfactory and somatosensory perception.
G. Choi

9.07 Statistics for Brain and Cognitive Science
______

Undergrad (Fall)
Prereq: 9.40
Units: 4-0-8
Lecture: MW9.30-11 (46-5056) Recitation: F11 (46-5056) +final
______
Provides students with the basic tools for analyzing experimental data, properly interpreting statistical reports in the literature, and reasoning under uncertain situations. Topics organized around three key theories: probability, statistical, and the linear model. Probability theory covers axioms of probability, discrete and continuous probability models, law of large numbers, and the Central Limit Theorem. Statistical theory covers estimation, likelihood theory, Bayesian methods, bootstrap and other Monte Carlo methods, as well as hypothesis testing, confidence intervals, elementary design of experiments principles and goodness-of-fit. The linear model theory covers the simple regression model and the analysis of variance. Places equal emphasis on theory, data analyses, and simulation studies.
E. N. Brown
No required or recommended textbooks

9.073[J] Statistics for Neuroscience Research
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject asHST.460[J])
Prereq: Permission of instructor
Units: 3-0-9
______
A survey of statistical methods for neuroscience research. Core topics include introductions to the theory of point processes, the generalized linear model, Monte Carlo methods, Bayesian methods, multivariate methods, time-series analysis, spectral analysis and state-space modeling. Emphasis on developing a firm conceptual understanding of the statistical paradigm and statistical methods primarily through analyses of actual experimental data.
E. N. Brown

9.09[J] Cellular and Molecular Neurobiology
______

Undergrad (Spring)
(Same subject as7.29[J])
Prereq: 7.05 or 9.01
Units: 4-0-8
______
Introduction to the structure and function of the nervous system. Emphasizes the cellular properties of neurons and other excitable cells. Includes the structure and biophysical properties of excitable cells, synaptic transmission, neurochemistry, neurodevelopment, integration of information in simple systems, and detection and information coding during sensory transduction.
T. Littleton, M. Heiman

9.10 Cognitive Neuroscience
______

Undergrad (Spring)
Prereq: 9.01
Units: 3-0-9
______
Explores the cognitive and neural processes that support attention, vision, language, social cognition, music understanding, emotion, motor control, and memory. Begins with the fundamental behavioral phenomena, then progresses to models based on brain systems in humans and animals, and ultimately models based on populations of neurons. Includes examples of clinical conditions and case studies in patients. Students prepare presentations summarizing journal articles.
R. Desimone, E. K. Miller

9.110[J] Nonlinear Control
______

Graduate (Spring)
(Same subject as2.152[J])
Prereq: 2.151, 6.241, 16.31, or permission of instructor
Units: 3-0-9
______
Introduction to nonlinear control and estimation in physical and biological systems. Nonlinear stability theory, Lyapunov analysis, Barbalat's lemma. Feedback linearization, differential flatness, internal dynamics. Sliding surfaces. Adaptive nonlinear control and estimation. Multiresolution bases, nonlinear system identification. Contraction analysis, differential stability theory. Nonlinear observers. Asynchronous distributed computation and learning. Concurrent synchronization, polyrhythms. Monotone nonlinear systems. Emphasizws application to physical systems (robots, aircraft, spacecraft, underwater vehicles, reaction-diffusion processes, machine vision, oscillators, internet), machine learning, computational neuroscience, and systems biology. Includes term projects.
J.-J. E. Slotine

9.12 Experimental Molecular Neurobiology
______

Undergrad (Spring) Institute Lab
Prereq: 9.01, Biology (GIR)
Units: 2-4-6
______
Experimental techniques in cellular and molecular neurobiology. Designed for students without previous experience in techniques of cellular and molecular biology. Experimental approaches include DNA manipulation, molecular clonging, protein biochemistry, dissection and culture of brain cells, synaptic protein analysis, immunocytochemistry, and fluorescent microscopy. One lab session plus one paper review session per week. Instruction and practice in written communication provided. Enrollment limited.
Y. Lin, G. Choi

9.123[J] Neurotechnology in Action
______

Graduate (Fall)
(Same subject as20.203[J])
Prereq: Permission of instructor
Units: 3-6-3
Lecture: TR2.30-4 (46-4062)
______
Offers a fast-paced introduction to numerous laboratory methods at the forefront of modern neurobiology. Comprises a sequence of modules focusing on neurotechnologies that are developed and used by MIT research groups. Each module consists of a background lecture and 1-2 days of firsthand laboratory experience. Topics typically include optical imaging, optogenetics, high throughput neurobiology, MRI/fMRI, advanced electrophysiology, viral and genetic tools, and connectomics.
A. Jasanoff, E. Boyden, M. Jonas
No required or recommended textbooks

9.14 Brain Structure and its Origins
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 9.01
Units: 3-0-9
______
Provides an introduction to functional neuroanatomy with a focus on mammals, aided by studies of comparative neuroanatomy and evolution and of brain development. Topics include early steps to a central nervous system, basic patterns of brain and spinal cord connections, regional development and differentiation, regeneration, motor and sensory pathways and structures, systems underlying motivations, innate action patterns, formation of habits, and various cognitive functions. Review of lab techniques. Optional brain dissections.
G. E. Schneider

9.15 Neural Circuits, Neuromodulatory, and Neuroendocrine Systems
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 9.01 or permission of instructor
Units: 3-0-9
______
Studies how neural circuits give rise to behavior, and how neuromodulatory systems and pharmacological intervention can influence these processes. Lectures and selected publications cover the fundamentals of neuropharmacology, neuromodulatory systems, and approaches to understand circuit mechanisms. Provides a historical view of various neurotransmitter or neuromodulatory systems as well as an understanding of how research is conducted at the forefront of neuroscience today. Instruction and practice in oral and written communication provided. Students present a primary research article and also submit a research proposal which they have the opportunity to revise based on feedback.
K. Tye

9.16 Cellular Neurophysiology
______

Undergrad (Fall)
(Subject meets with9.160)
Prereq: 9.40
Units: 3-0-9
Lecture: TR11-12.30 (46-4062) +final
______
Surveys the mechanisms of neuronal communication. Covers ion channels in excitable membrane, single cell computation, synaptic transmission, and synaptic plasticity. Correlates the properties of ion channels and synaptic transmission with their physiological function. Discusses the organizational principles for the formation of functional neural networks at synaptic and cellular levels. Involves discussion of primary literature. Students taking graduate version complete additional assignments.
W. Xu
Textbooks (Fall 2016)

9.160 Cellular Neurophysiology
(New)
______

Graduate (Fall)
(Subject meets with9.16)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR11-12.30 (46-4062) +final
______
Surveys the mechanisms of neuronal communication. Covers ion channels in excitable membrane, single cell computation, synaptic transmission, and synaptic plasticity. Correlates the properties of ion channels and synaptic transmission with their physiological function. Discusses the organizational principles for the formation of functional neural networks at synaptic and cellular levels. Involves discussion of primary literature. Students taking graduate version complete additional assignments.
W. Xu
Textbooks (Fall 2016)

9.17 Systems Neuroscience Laboratory
______

Undergrad (Fall) Institute Lab
Prereq: 9.40 or permission of instructor;Coreq: 9.07
Units: 2-4-6
Lecture: M4 (46-1015) Lab: R1-5 (46-1024) Recitation: T9 (46-1015)
______
Consists of a series of laboratories designed to give students experience with basic techniques for conducting systems neuroscience research. Includes sessions on anatomical, neurophysiological, and data acquisition and analysis techniques, and how these techniques are used to study nervous system function. Involves the use of experimental animals. Assignments include weekly preparation for lab sessions, two major lab reports and a series of basic computer programming tutorials (MATLAB). Instruction and practice in written communication provided. Enrollment limited.
M. Wilson, M. Harnett
No required or recommended textbooks

9.173[J] Noninvasive Imaging in Biology and Medicine
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as20.483[J],22.56[J],HST.561[J])
Prereq: 18.03, 8.03, or permission of instructor
Units: 3-0-9
______
Background in the theory and application of noninvasive imaging methods in biology and medicine, with emphasis on neuroimaging. Focuses on the modalities most frequently used in scientific research (x-ray CT, PET/SPECT, MRI, and optical imaging), and includes discussion of molecular imaging approaches used in conjunction with these scanning methods. Lectures are supplemented by in-class discussions of problems in research and demonstrations of imaging systems.
A. Jasanoff

9.175[J] Robotics
______

Graduate (Spring)
(Same subject as2.165[J])
Prereq: 2.151 or permission of instructor
Units: 3-0-9
______
Dynamic analysis, design, and control of robots. Forward and inverse kinematics and dynamics of multi-input, multi-output rigid body systems. Computed torque control. Adaptive control. System identification. Force feedback, adaptive visual servoing. Task planning, teleoperation. Elements of biological planning and control. Motor primitives, entrainment, locomotion, active sensing, binding models. Term projects.
J.-J. E. Slotine, H. Asada

9.18[J] Developmental Neurobiology
______

Undergrad (Spring)
(Same subject as 7.49[J])
(Subject meets with7.69[J],9.181[J])
Prereq: 9.01, 7.03, 7.05, or permission of instructor
Units: 3-0-9
______

9.181[J] Developmental Neurobiology
______

Graduate (Spring)
(Same subject as7.69[J])
(Subject meets with 7.49[J],9.18[J])
Prereq: 9.011 or permission of instructor
Units: 3-0-9
______
Considers molecular control of neural specification, formation of neuronal connections, construction of neural systems, and the contributions of experience to shaping brain structure and function. Topics include: neural induction and pattern formation, cell lineage and fate determination, neuronal migration, axon guidance, synapse formation and stabilization, activity-dependent development and critical periods, development of behavior. In addition to final exam, analysis and presentation of research papers required for final grade. Students taking graduate version complete additional assignments. Students taking graduate version complete additional readings that will be addressed in their mid-term and final exams.
E. Nedivi, M. Heiman

9.20 Animal Behavior
______

Undergrad (Fall) HASS Social Sciences
Prereq: 9.00
Units: 3-0-9
Lecture: MWF4 (46-3310) +final
______
Reviews studies of animal behavior to stress major ideas and principles, with emphasis on concepts developed in ethology and sociobiology. Examines foraging and feeding, defensive and aggressive behavior, courtship and reproduction, migration and navigation, as well as various social activities and communication. Considers inherited abilities, motivational systems and motor patterns, together with influences of various types of learning. Reviews both field and laboratory studies, and considers human behavior in the context of primate studies.
G. E. Schneider
Textbooks (Fall 2016)

9.24 Disorders and Diseases of the Nervous System
______

Undergrad (Spring)
Prereq: 9.00, 9.01, 9.09
Units: 3-0-9
______
Topics examined include regional functional anatomy of the CNS; brain systems and circuits; neurodevelopmental disorders including autism; neuropsychiatric disorders such as schizophrenia; neurodegenerative diseases such as Parkinson's and Alzheimer's; autoimmune disorders such as multiple sclerosis; gliomas. Emphasis on diseases for which a molecular mechanism is understood. Diagnostic criteria, clinical and pathological findings, genetics, model systems, pathophysiology, and treatment are discussed for individual disorders and diseases.
M. Sur

9.26[J] Principles and Applications of Genetic Engineering for Biotechnology and Neuroscience
______

Undergrad (Spring)
(Same subject as20.205[J])
Prereq: 7.28, 7.32, or 20.020; 9.01 or 9.09
Units: 3-0-9
______
Covers principles underlying current and future genetic engineering approaches, ranging from single cellular organisms to whole animals. Focuses on development and invention of technologies for engineering biological systems at the genomic level, and applications of engineered biological systems for medical and biotechnological needs, with particular emphasis on genetic manipulation of the nervous system. Design projects by students.
F. Zhang

9.272[J] Topics in Neural Signal Processing
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject asHST.576[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Presents signal processing and statistical methods used to study neural systems and analyze neurophysiological data. Topics include state-space modeling formulated using the Bayesian Chapman-Kolmogorov system, theory of point processes, EM algorithm, Bayesian and sequential Monte Carlo methods. Applications include dynamic analyses of neural encoding, neural spike train decoding, studies of neural receptive field plasticity, algorithms for neural prosthetic control, EEG and MEG source localization. Students should know introductory probability theory and statistics. Alternate years.
E. N. Brown

9.28 Current Topics in Developmental Neurobiology
______

Undergrad (Spring)
Prereq: None.Coreq: 9.18
Units: 3-0-6
______
Considers recent advances in the field of developmental neurobiology based on primary research articles that address molecular control of neural specification, formation of neuronal connections, construction of neural systems, and the contributions of experience to shaping brain structure and function. Also considers new techniques and methodologies as applied to the field. Students critically analyze articles and prepare concise and informative presentations based on their content. Instruction and practice in written and oral communication provided. Requires class participation, practice sessions, and presentations.
E. Nedivi

9.285[J] Neural Coding and Perception of Sound
______

Graduate (Spring)
(Same subject asHST.723[J])
Prereq: Permission of instructor
Units: 3-1-8
______
Neural structures and mechanisms mediating the detection, localization, and recognition of sounds. Discussion of how acoustic signals are coded by auditory neurons, the impact of these codes on behavioral performance, and the circuitry and cellular mechanisms underlying signal transformations. Topics include temporal coding, neural maps and feature detectors, learning and plasticity, and feedback control. General principles are conveyed by theme discussions of auditory masking, sound localization, musical pitch, cochlear implants, and auditory scene analysis. Follows Harvard FAS calendar.
B. Delgutte, M. C. Brown, J. McDermott, D. Polley

9.301[J] Neural Plasticity in Learning and Memory
______

Graduate (Spring)
(Same subject as7.98[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://web.mit.edu/7.98/
______
Examination of the role of neural plasticity during learning and memory of invertebrates and mammals. Detailed critical analysis of the current literature of molecular, cellular, genetic, electrophysiological, and behavioral studies. Student-directed presentations and discussions of original papers supplemented by introductory lectures. Juniors and seniors require instructor's permission.
S. Tonegawa, W. Quinn

9.31 Neurobiology of Learning and Memory
______

Undergrad (Fall)
Prereq: 9.01
Units: 4-0-8
Lecture: MW10.30-12 (46-5193) Recitation: F10.30 (46-5193)
______
Surveys the mechanisms supporting plasticity in neurons, focusing on how it contributes to learning in several systems. Examines cellular forms of associative plasticity, including long-term potentiation and depression, homeostatic plasticity, and depotentiation. Relates these phenomena to associative memory in animal systems and humans. Completion of 9.09 recommended.
M. Constantine-Paton
Textbooks (Fall 2016)

9.32 Genes, Circuits, and Behavior
______

Undergrad (Spring)
Prereq: 9.09, 9.10, 9.16, or 9.18
Units: 3-0-9
______
Focuses on understanding molecular and cellular mechanisms of circuitry development, function and plasticity, and their relevance to normal and abnormal behaviors/psychiatric disorders. Highlights cutting-edge technologies for neuroscience research. Students build professional skills through presentations and critical evaluation of original research papers.
G. Feng

9.322[J] Genetic Methods in Neurobiology
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as7.67[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://mit.edu/7.67j/
______
Presents selected topics in which genetic analysis informs neurobiological issues, including action potential conduction and synaptic release in Drosophila, axon guidance in nematodes and Drosophila, olfaction and orienting behavior in nematodes. Studies hippocampal and cortical circuitry and function in mice, as well as genetically-determined and genetically-influenced human traits and diseases. Reviews methods such as mutagenesis, gene knockouts and transgene constructs, tissue-specific expression vectors, optically, chemically and thermally-inducible gene activation and inactivation.
W. G. Quinn

9.33 Your Brain: A User's Guide
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Elective
Prereq: None
Units: 3-0-9
______
Provides students with perspective on brain functions and behaviors of particular relevance to individuals their age. Using library databases, students conduct scholarly research and compare the attitudes conveyed in magazines and newspapers with facts from neurobiology textbooks, scientific reviews, and basic research articles. Each student presents and leads a discussion on a topic related to a behavior of his or her choosing. Preference to freshmen and non-Course 9 majors; limited to 17.
M. Constantine-Paton

9.34[J] Biomechanics and Neural Control of Movement
______

Graduate (Spring)
(Same subject as2.183[J])
(Subject meets with2.184)
Prereq: 2.004, 2.04A, or permission of instructor
Units: 3-0-9
______
Quantitative knowledge of human movement behavior is important in a growing number of engineering applications (medical and rehabilitation technology, athletic and military equipment, human-computer interaction, vehicle performance, etc.). Presents a quantitative, model-based description of how biomechanical and neural factors interact in human sensory-motor behavior, focusing mainly on the upper limbs. Students survey recent literature on how motor behavior is controlled, comparing biological and robotic approaches to similar tasks. Topics may include a review of relevant neural, muscular and skeletal physiology, neural feedback and "equilibrium-point" theories, co-contraction strategies, impedance control, kinematic redundancy, optimization, intermittency, contact tasks and tool use. Students taking the graduate version will complete additional assignments.
N. Hogan

9.35 Perceptual Systems
______

Undergrad (Spring)
Prereq: 9.00, 9.01; or permission of instructor
Units: 4-0-8
______
Studies how the senses work and how physical stimuli are transformed into signals in the nervous system. Examines how the brain uses those signals to make inferences about the world, and uses illusions and demonstrations gain insight into those inferences. Emphasizes audition and vision, with some discussion of touch, taste, and smell. Provides experience with psychophysical methods.
J. McDermott

9.357 Current Topics in Vision Science
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-7
______
Advanced seminar on issues of current interest in human and machine vision. Topics vary from year to year. Participants discuss current literature as well as their ongoing research.
E. H. Adelson

9.40 Introduction to Neural Computation
______

Undergrad (Spring)
Prereq: 6.0002, 9.01
Units: 4-0-8
______
Introduces quantitative approaches to understanding brain and cognitive functions. Topics include mathematical description of neurons, the response of neurons to sensory stimuli, simple neuronal networks, statistical inference and decision making. Also covers foundational quantitative tools of data analysis in neuroscience: correlation, convolution, spectral analysis, principal components analysis. Mathematical concepts include simple differential equations and linear algebra.
M. Fee

9.41 Research and Communication in Neuroscience and Cognitive Science
______

Undergrad (Fall)
Prereq: 9.URG, permission of instructor
Units: 2-12-4
Lecture: M EVE (7-9 PM) (46-5056) Lab: TBA
______
Emphasizes research and scientific communication. Instruction and practice in written and oral communication provided. Based on results of his/her UROP research, each student creates a full-length paper and a poster as part of an oral presentation at the end of the term. Other assignments include peer editing and reading/critiquing published research papers. Prior to starting class, students must have collected enough data from their UROP research projects to write a paper. Limited to juniors and seniors.
L. Schulz
No textbook information available

9.42 The Brain and Its Interface with the Body
(New)
______

Undergrad (Spring)
Prereq: 7.28, 9.09, or permission of instructor
Units: 3-0-9
______
Covers a range of topics, such as brain-immune system interaction, the gut-brain axis, and bioengineering approaches for studying the brain and its interactions with different organs. Explores how these interactions may be involved in nervous system disease processes.
F. Zhang

9.422[J] Principles of Neuroengineering
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as20.452[J],MAS.881[J])
(Subject meets with20.352)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://neuro.media.mit.edu/classes/prinneuro/
______
Covers how to innovate technologies for brain analysis and engineering, for accelerating the basic understanding of the brain, and leading to new therapeutic insight and inventions. Focuses on using physical, chemical and biological principles to understand technology design criteria governing ability to observe and alter brain structure and function. Topics include optogenetics, noninvasive brain imaging and stimulation, nanotechnologies, stem cells and tissue engineering, and advanced molecular and structural imaging technologies. Includes design projects. Designed for students with engineering maturity who are ready for design. Students taking graduate version complete additional assignments.
E. S. Boyden, III

9.455[J] Revolutionary Ventures: How to Invent and Deploy Transformative Technologies
______

Graduate (Fall)
(Same subject as15.128[J],20.454[J],MAS.883[J])
Prereq: Permission of instructor
Units: 2-0-7
URL: http://neuro.media.mit.edu/classes/neuroven/
Lecture: R2-4 (E15-341)
______
Seminar on envisioning and building ideas and organizations to accelerate engineering revolutions. Focuses on emerging technology domains, such as neurotechnology, imaging, cryotechnology, gerontechnology, and bio-and-nano fabrication. Draws on historical examples as well as live case studies of existing or emerging organizations, including labs, institutes, startups, and companies. Goals range from accelerating basic science to developing transformative products or therapeutics. Each class is devoted to a specific area, often with invited speakers, exploring issues from the deeply technical through the strategic. Individually or in small groups, students prototype new ventures aimed at inventing and deploying revolutionary technologies.
J. Bonsen, J. Jacobson
No textbook information available

9.46 Neuroscience of Morality
______

Undergrad (Fall)
Prereq: 9.00, 9.01; 9.10, 9.20, or 9.85
Units: 3-0-9
Lecture: MW10.30-12 (46-1015) +final
______
Advanced seminar that covers both classic and cutting-edge primary literature from psychology and the neuroscience of morality. Addresses questions about how the human brain decides which actions are morally right or wrong (including neural mechanisms of empathy and self-control), how such brain systems develop over childhood and differ across individuals and cultures, and how they are affected by brain diseases (such as psychopathy, autism, tumors, or addiction). Instruction and practice in written and oral communication provided. Limited to 24.
R. Saxe
No required or recommended textbooks

9.48[J] Philosophical Issues in Brain Science
______

Undergrad (Fall) HASS Humanities Communication Intensive HASS
Not offered regularly; consult department
(Same subject as24.08[J])
Prereq: None
Units: 3-0-9
______
An introduction to some central philosophical questions about the mind, specifically those intimately connected with contemporary psychology and neuroscience. Discussions focus on arguments over innate concepts; 'mental images' as pictures in the head; whether color is in the mind or in the world; and whether there can be a science of consciousness. Explains the relevant parts of psychology and neuroscience as the subject proceeds.
A. Byrne


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Produced: 29-SEP-2016 06:37 AMFall 2016 Course 9: Brain and Cognitive Sciences
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Course 9: Brain and Cognitive Sciences
Fall 2016


9.50 Research in Brain and Cognitive Sciences
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: 9.00, permission of instructor
Units: 0-12-0
TBA.
______
Laboratory research in brain and cognitive science, using physiological, anatomical, pharmacological, developmental, behavioral, and computational methods. Each student carries out an experimental study under the direction of a member of the faculty. Project must be approved in advance by the faculty supervisor and the Director of the Undergraduate Program. Written presentation of results is required.
Consult L. Schulz
No textbook information available

9.520[J] Statistical Learning Theory and Applications
______

Graduate (Fall)
(Same subject as6.860[J])
Prereq: 6.867, 6.041B, 18.06, or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/9.520/www/
Lecture: MW1-2.30 (46-3310)
______
Provides students with the knowledge needed to use and develop advanced machine learning solutions to challenging problems. Covers foundations and recent advances of machine learning in the framework of statistical learning theory. Focuses on regularization techniques key to high-dimensional supervised learning. Starting from classical methods such as regularization networks and support vector machines, addresses state-of-the-art techniques based on principles such as geometry or sparsity, and discusses a variety of algorithms for supervised learning, feature selection, structured prediction, and multitask learning. Also focuses on unsupervised learning of data representations, with an emphasis on hierarchical (deep) architectures.
T. Poggio, L. Rosasco
No required or recommended textbooks

9.523[J] Aspects of a Computational Theory of Intelligence
______

Graduate (Fall)
(Same subject as6.861[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: F11-2 (46-3189)
______
Integrates neuroscience, cognitive and computer science to explore the nature of intelligence, how it is produced by the brain, and how it can be replicated in machines. Discusses an array of current research connected through an overarching theme of how it contributes to a computational account of how humans analyze dynamic visual imagery to understand objects and actions in the world.
T. Poggio, S. Ullman
No required or recommended textbooks

9.54 Computational Aspects of Biological Learning
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 9.40
Units: 3-0-9
______
Takes a computational approach to learning in the brain by neurons and synapses. Examines supervised and unsupervised learning as well as possible biological substrates, including Hebb synapses and the related topics of Oja flow and principal components analysis. Discusses hypothetical computational primitives in the nervous system, and the implications for unsupervised learning algorithms underlying the development of tuning properties of cortical neurons. Also focuses on a broad class of biologically plausible learning strategies.
T. Poggio, S. Ullman

9.56[J] Abnormal Language
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject as24.907[J])
Prereq: 24.900 or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduction to the linguistic study of language pathology, concentrating on experimental approaches and theoretical explanations. Discussion of Specific Language Impairment, Down syndrome, William's syndrome, autism, normal aging, Parkinson's disease, Alzheimer's disease, hemispherectomy, and aphasia. Focuses on the comparison of linguistic abilities among these syndromes, while drawing clear comparisons with first- and second-language acquisition. Topics include the lexicon, morphology, syntax, semantics, and pragmatics. Relates the lost linguistic abilities in these syndromes to properties of the brain.
K. Wexler

9.583[J] Functional Magnetic Resonance Imaging: Data Acquisition and Analysis
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject asHST.583[J])
Prereq: 18.05; 18.06 or permission of instructor
Units: 2-3-7
______
Provides background necessary for designing, conducting, and interpreting fMRI studies in the human brain. Covers in depth the physics of image encoding, mechanisms of anatomical and functional contrasts, the physiological basis of fMRI signals, cerebral hemodynamics, and neurovascular coupling. Also covers design methods for stimulus-, task-driven and resting-state experiments, as well as workflows for model-based and data-driven analysis methods for data. Instruction in brain structure analysis and surface- and region-based analyses. Laboratory sessions include data acquisition sessions at the 3 Tesla MRI scanner at MIT and the Connectom and 7 Tesla scanners at the MGH/HST Martinos Center, as well as hands-on data analysis workshops. Introductory or college-level neurobiology, physics, and signal processing are helpful.
S. Whitfield-Gabrieli, J. Polimeni, A. Yendiki

9.59[J] Laboratory in Psycholinguistics
______

Undergrad (Spring) Institute Lab
(Same subject as24.905[J])
Prereq: 9.00 or 24.900
Units: 3-3-6
______
Hands-on experience designing, conducting, analyzing, and presenting experiments on the structure and processing of human language. Focuses on constructing, conducting, analyzing, and presenting an original and independent experimental project of publishable quality. Develops skills in reading and writing scientific research reports in cognitive science, including evaluating the methods section of a published paper, reading and understanding graphical displays and statistical claims about data, and evaluating theoretical claims based on experimental data. Instruction and practice in oral and written communication provided.
E. Gibson

9.601[J] Language Acquisition I
______

Graduate (Fall)
(Same subject as24.949[J])
Prereq: Permission of instructor
Units: 3-0-6
Lecture: M2-5 (32-D461)
______
Lectures, reading, and discussion of current theory and data concerning the psychology and biology of language acquisition. Emphasizes learning of syntax, semantics, and morphology, together with some discussion of phonology, and especially research relating grammatical theory and learnability theory to empirical studies of children.
L. Koring
No textbook information available

9.611[J] Natural Language and the Computer Representation of Knowledge
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as6.863[J])
Prereq: 6.034
Units: 3-3-6
______
Explores the relationship between computer representation of knowledge and the structure of natural language. Emphasizes development of analytical skills necessary to judge the computational implications of grammatical formalisms, and uses concrete examples to illustrate particular computational issues. Efficient parsing algorithms for context-free grammars; Treebank grammars and statistical parsing. Question answering systems. Extensive laboratory work on building natural language processing systems.
R. C. Berwick

9.63 Laboratory in Visual Cognition
______

Not offered academic year 2016-2017Undergrad (Fall) Institute Lab
Prereq: 9.00
Units: 2-1-9
Subject Cancelled Subject Cancelled
______
Teaches principles of experimental methods in human visual perception and attention, including how to design, conduct, analyze, and present experiments in visual cognition. Combines lectures and hands-on experimental exercises. Requires two experimental projects, at least one of which is conducted independently; the other may be done as part of a team. Assignments include individual reports on experimental designs, written articles, and presentations critiquing three team experiments observed in class. Instruction and practice in written and oral communication provided. Experience with MATLAB is recommended. Limited to 16.
P. Sinha
No required or recommended textbooks

9.65 Cognitive Processes
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Social Sciences
Prereq: 9.00
Units: 3-0-9
______
Introduction to human information processing and learning. Topics include the nature of mental representation and processing, memory and learning, pattern recognition, attention, imagery and mental codes, concepts and prototypes, as well as reasoning and problem-solving.
M. C. Potter

9.66[J] Computational Cognitive Science
______

Undergrad (Fall)
(Same subject as6.804[J])
(Subject meets with9.660)
Prereq: 6.008, 6.036, 6.041B, 9.40, 18.05, or permission of instructor
Units: 3-0-9
9.66: Lecture: TR1-2.30 (46-3189)
______
Introduction to computational theories of human cognition. Focus on principles of inductive learning and inference, and the representation of knowledge. Computational frameworks covered include Bayesian and hierarchical Bayesian models; probabilistic graphical models; nonparametric statistical models and the Bayesian Occam's razor; sampling algorithms for approximate learning and inference; and probabilistic models defined over structured representations such as first-order logic, grammars, or relational schemas. Applications to understanding core aspects of cognition, such as concept learning and categorization, causal reasoning, theory formation, language acquisition, and social inference. Graduate students complete a final project.
J. Tenenbaum
9.66: No required or recommended textbooks

9.660 Computational Cognitive Science
______

Graduate (Fall)
(Subject meets with6.804[J],9.66[J])
Prereq: Permission of instructor
Units: 3-0-9
9.660: Lecture: TR1-2.30 (46-3189)
______
Introduction to computational theories of human cognition. Focuses on principles of inductive learning and inference, and the representation of knowledge. Computational frameworks include Bayesian and hierarchical Bayesian models, probabilistic graphical models, nonparametric statistical models and the Bayesian Occam's razor, sampling algorithms for approximate learning and inference, and probabilistic models defined over structured representations such as first-order logic, grammars, or relational schemas. Applications to understanding core aspects of cognition, such as concept learning and categorization, causal reasoning, theory formation, language acquisition, and social inference. Graduate students complete a final project.
J. Tenenbaum
9.660: No textbook information available

9.71 Functional MRI Investigations of the Human Brain
______

Undergrad (Fall)
Prereq: 9.07, 18.05, or permission of instructor
Units: 3-0-9
Lecture: T EVE (7-10 PM) (46-3015)
______
Covers design and interpretation of fMRI experiments, and the relationship between fMRI and other techniques. Focuses on localization of cognitive function in the human brain. Students write papers and give presentations, explain and critique published papers, and design but do not conduct their own fMRI experiments. Upon completion, students should be able to understand and critique published fMRI papers and have a good grasp of what is known about localization of cognitive function from fMRI. Instruction and practice in written and oral communication provided. Limited to 12.
N. G. Kanwisher
No required or recommended textbooks

9.77 Computational Perception
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 9.00, 9.40; 9.35 or 9.65
Units: 3-0-9
______
Begins with a review of the experimental paradigms, findings and theories used to evaluate the capabilities and limits of human visual perception. Assesses how knowledge of human perception may be used to guide machine vision systems. Second part of the subject focuses on models in computational perception. Describes how computer vision systems can perform image analysis and synthesis; face, object and scene perception; texture synthesis, segmentation, and navigation. Introduces various simulation methods. A MATLAB-based project in computational perception is required. Limited to 8.
E. Adelson

9.822[J] Psychology and Economics
______

Graduate (Spring)
(Same subject as14.137[J])
Prereq: None
Units: 4-0-8
______
Examines "psychology appreciation" for economics students. Aims to enhance knowledge and intuition about psychological processes in areas relevant to economics. Increases understanding of psychology as an experimental discipline, with its own distinct rules and style of argument. Topics include self-knowledge, cognitive dissonance, self-deception, emotions, social norms, self-control, learning, mental accounting, memory, individual and group behavior, and some personality and psycho-analytic models. Within each of these topics, we showcase effective and central experiments and discuss their role in the development of psychological theory. Term paper required.
D. Prelec

9.85 Infant and Early Childhood Cognition
______

Undergrad (Fall) HASS Social Sciences
Prereq: 9.00
Units: 3-0-9
Lecture: TR1-2.30 (46-3002)
______
Introduction to cognitive development focusing on childrens' understanding of objects, agents, and causality. Develops a critical understanding of experimental design. Discusses how developmental research might address philosophical questions about the origins of knowledge, appearance and reality, and the problem of other minds. Provides instruction and practice in written communication as necessary to research in cognitive science (including critical reviews of journal papers, a literature review and an original research proposal), as well as instruction and practice in oral communication in the form of a poster presentation of a journal paper.
L. Schulz
No required or recommended textbooks

9.901 Responsible Conduct in Science
______

Graduate (IAP)
Prereq: None
Units: 1-0-1 [P/D/F]
______
Provides instruction and dialogue on practical ethical issues relating to the responsible conduct of human and animal research in the brain and cognitive sciences. Specific emphasis on topics relevant to young researchers including data handling, animal and human subjects, misconduct, mentoring, intellectual property, and publication. Preliminary assigned readings and initial faculty lecture followed by discussion groups of four to five students each. A short written summary of the discussions submitted at the end of each class. See IAP Guide for registration information.
M. Wilson

9.91 Independent Study in Brain and Cognitive Sciences
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: 9.00 and any other two subjects in Brain and Cognitive Sciences; permission of instructor
Units arranged
TBA.
______
Individual study of a topic under the direction of a member of the faculty.
Consult Staff
No textbook information available

9.919 Teaching Brain and Cognitive Sciences
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
For teaching assistants in Brain and Cognitive Sciences, in cases where teaching assignment is approved for academic credit by the department.
Staff
No textbook information available

9.921 Research in Brain and Cognitive Sciences
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Guided research under the sponsorship of individual members of the faculty. Ordinarily restricted to candidates for the doctoral degree in Course 9.
Staff
No textbook information available

9.941 Graduate Thesis Proposal
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Students submit written proposals for thesis according to stated deadlines.
Staff
No textbook information available

9.95 Research Topics in Neuroscience
______

Undergrad (IAP) Can be repeated for credit
Prereq: None
Units: 1-0-0 [P/D/F]
______
Lecture series that highlights faculty research in various fields of neuroscience. Each of the six lectures focuses on a specific area of brain research, delineating issues, methods, and findings pertinent to the topic. Exam administered during seventh and final class session. Pre-register on WebSIS; must attend first class.
P. H. Schiller

9.97 Introduction to Neuroanatomy
______

Undergrad (IAP)
Prereq: None
Units: 1-0-0 [P/D/F]
______
Intensive introduction to neuroanatomy that consists of lectures, demonstrations, and interactive laboratories, including a brain dissection. No prior knowledge of neuroanatomy required, although general knowledge of brain structures is helpful. Pre-register on WebSIS; must attend first class. Limited to 100.
R. Ellis-Behnke

9.S51 Special Subject in Brain and Cognitive Sciences
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: 9.00 and any other two subjects in Brain and Cognitive Sciences
Units arranged
______
Undergraduate study in brain and cognitive sciences; covers material not offered in regular curriculum.
Consult Staff

9.S52 Special Subject in Brain and Cognitive Sciences
______

Undergrad (Spring) Can be repeated for credit
Prereq: 9.00 and any other two subjects in Brain and Cognitive Sciences
Units arranged
______
Undergraduate study in brain and cognitive sciences; covers material not offered in regular curriculum.
Consult Staff

9.S911-9.S917 Special Subject in Brain and Cognitive Sciences
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
9.S911: Meets 9/22 to 9/29. Lecture: R EVE (5-7 PM) (46-3310)
Subject Cancelled 9.S912 Cancelled
9.S915: Lecture: TR3-4.30 (46-5193)
9.S916: Lecture: R10-11.30 (46-5193)
9.S917: TBA.
______
Advanced graduate study in brain and cognitive sciences; covers material not offered in regular curriculum. 9.S911 is graded P/D/F.
J. Di Carlo
9.S911: No textbook information available
9.S915: No textbook information available
9.S916: No textbook information available
9.S917: No textbook information available

9.S92 Special Subject in Brain and Cognitive Sciences
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: 9.00
Units arranged
TBA.
______
Undergraduate study in brain and cognitive sciences; covers material not offered in regular curriculum.
Consult Staff
No textbook information available

9.S93-9.S99 Special Subject in Brain and Cognitive Sciences
______

Undergrad (IAP)
Prereq: None
Units arranged [P/D/F]
______
For undergraduate study in brain and cognitive sciences during Independent Activities Period; covers material not offered in regular curriculum. See IAP Guide for details.
Staff

9.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of a Ph.D. thesis; to be arranged by the student and an appropriate MIT faculty member.
Staff
Textbooks arranged individually

9.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually

9.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Individual participation in an ongoing research project.
Consult Staff
Textbooks arranged individually


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Produced: 29-SEP-2016 06:37 AMFall 2016 Course 10: Chemical Engineering
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Course 10: Chemical Engineering
Fall 2016


10.00 Molecule Builders
______

Undergrad (Spring)
Prereq: Chemistry (GIR), Physics I (GIR)
Units: 1-6-2
______
Project-based introduction to the applications of engineering design at the molecular level. Working in teams, students complete an open-ended design project that focuses on a topic such as reactor or biomolecular engineering, chemical process design, materials and polymers, or energy. Provides students practical exposure to the field of chemical engineering as well as potential opportunities to continue their project designs in national/international competitions. Limited to 36; preference to first year students.
B. D. Olsen

10.01 Ethics for Engineers
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.082,2.900,6.904,10.01,22.014)
Prereq: None
Units: 2-0-4
Lecture: M3-5 (66-144, 36-153) or T3-5 (37-212) or T EVE (7.30-9.30 PM) (66-144) or W3-5 (36-153)
______
Integrates classical readings that provide an overview of ethics with a survey of case studies that focus on ethical problems arising in the practice of engineering. Readings taken from a variety of sources, such as Aristotle, Machiavelli, Bacon, Hobbes, Locke, the Founding Fathers, and the Bible. Case studies include written analyses and films that address engineering disasters, biotechnology, court cases, ethical codes, and the ultimate scope and aims of engineering.
D. Doneson, B. L. Trout
No textbook information available

10.02 Foundations of Entrepreneurship for Engineers
______

Undergrad (Spring)
Prereq: None
Units: 3-0-9
______
Studies economic and leadership foundations of entrepreneurship as they relate to engineering. Case studies illustrate major impacts of engineering on the world and examine the leaders responsible for such impacts. Authors include Franklin, Keynes, Leonardo, Lincoln, Locke, Machiavelli, Marx, Schmidt, Schumpeter, Smith, Thiel, and Tocqueville. Discusses topics such as the difference between an entrepreneur and a manager, the entrepreneur as founder, and characteristics of principled entrepreneurship.
D. Doneson, B. L. Trout

10.03[J] Advances in Biomanufacturing
______

Undergrad (Fall, Spring); second half of term
(Same subject as 7.458[J])
(Subject meets with7.548[J],10.53[J])
Prereq: None
Units: 1-0-2 [P/D/F]
Begins Oct 24. Lecture: TR11 (66-148)
______
Seminar examines how biopharmaceuticals, an increasingly important class of pharmaceuticals, are manufactured. Topics range from fundamental bioprocesses to new technologies to the economics of biomanufacturing. Also covers the impact of globalization on regulation and quality approaches as well as supply chain integrity. Students taking graduate version complete additional assignments.
J. C. Love, A. Sinskey, S. Springs
No textbook information available

10.04[J] A Philosophical History of Energy
______

Undergrad (Spring) HASS Humanities Communication Intensive HASS
(Same subject as24.114[J])
Prereq: None
Units: 3-0-9
______
Philosophic and historical approach to conceptions of energy through the 19th century. Relation of long standing scientific and philosophic problems in the field of energy to 21st-century debates. Topics include the development of thermodynamics and kinetic theories, the foundation of the scientific project, the classical view of energy, and the harnessing of nature. Authors include Bacon, Boltzmann, Carnot, Compte, Descartes, Gibbs, Plato, Aristotle, Leibniz, Kant, Hegel, Mill, Peirce, Whitehead, and Maxwell. Key texts and controversies form topics of weekly writing assignments and term papers.
B. L. Trout, A. Schulman

10.05 Foundational Analyses of Problems in Energy and the Environment
(New)
______

Undergrad (Spring)
Prereq: None
Units: 3-0-9
______
Investigates key texts and papers on the foundational thought of current issues in energy and environmental science. Builds an understanding of key debates (scientific, ethical, and political). Aims to inform solutions to key problems related to procurement of energy and environmental degradation. Topics address alternative energy technologies and fossil fuel utilization and emissions, especially carbon dioxide, carbon dioxide sequestration, and geoengineering. Foundational readings from Homer and Greek playwrights, Aristotle, Genesis, Bacon, Locke, Rousseau, Coleridge, Carnot, Clausius, Marx, Heidegger, Carson, Gore, Singer, and Brundtland. Assignments include weekly analyses of readings, videos and related engineering calculations in addition to a final project. Limited to 18.
B. L. Trout

10.10 Introduction to Chemical Engineering
______

Undergrad (Fall, Spring)
Prereq: Chemistry (GIR), Physics I (GIR), Calculus I (GIR)
Units: 4-0-8
Lecture: MWF2 (56-114) Recitation: T12 (66-168) +final
______
The diverse applications of chemical engineering are explored through example problems. Solutions require application of fundamental concepts of mass and energy conservation to batch and continuous systems, involving chemical and biological processes. Computer skills and the elements of engineering design are taught in the context of these example problems. The objective is to acquaint the student with the field of chemical engineering and to enable use of computer methods to solve chemical and biological engineering problems.
B. S. Johnston, K. L. J. Prather
Textbooks (Fall 2016)

10.213 Chemical and Biological Engineering Thermodynamics
______

Undergrad (Spring)
Prereq: 5.60, 10.10
Units: 4-0-8
______
Thermodynamics of multicomponent, multiphase chemical and biological systems. Applications of first, second, and third laws of thermodynamics to open and closed systems. Properties of mixtures, including colligative properties, chemical reaction equilibrium, and phase equilibrium; non-ideal solutions; power cycles; refrigeration; separation systems.
K. K. Gleason, H. D. Sikes

10.22 Molecular Engineering
______

Undergrad (Spring)
Prereq: 5.60, 10.213
Units: 3-0-9
______
Introduces molecular concepts in relation to engineering thermodynamics. Includes topics in statistical mechanics, molecular description of gases and liquids, property estimation, description of equilibrium and dynamic properties of fluids from molecular principles, and kinetics of activated processes. Also covers some basic aspects of molecular simulation and applications in systems of engineering interest.
G. C. Rutledge, P. S. Doyle

10.25 Industrial Chemistry and Chemical Process Pathways
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: Chemistry (GIR), 10.213, 10.37
Units: 3-0-6
______
Chemical and engineering principles involved in creation and operation of viable industrial processes. Topics: analysis of process chemistry by p-pathways (i.e., radical, ionic, and pericyclic reactions of organic syntheses) and d-pathways (i.e., catalysis by transition-metal complexes). Use of reaction mechanisms for inference of co-product formation, kinetics, and equilibria: process synthesis logic related to reaction selectivity, recycle, separations. Illustrations drawn from current and contemplated commercial practice.
P. S. Virk

10.26 Chemical Engineering Projects Laboratory
______

Undergrad (Spring)
(Subject meets with10.27,10.29)
Prereq: 2.671, 3.014, 5.310, 7.02, 12.335, or 1.106 and 1.107; 10.302; or permission of instructor
Units: 3-8-4
URL: http://web.mit.edu/10.26/www/
______
Projects in applied chemical engineering research. Students work in teams on one project for the term. Projects often suggested by local industry. Includes training in research planning and project management, execution of experimental work, data analysis, oral presentation skills and individual report writing, and team-building.
C. K. Colton, B. S. Johnston, B. D. Burrell, G. C. Rutledge

10.27 Energy Engineering Projects Laboratory
______

Undergrad (Spring)
(Subject meets with10.26,10.29)
Prereq: 2.671, 3.014, 5.310, 7.02, 12.335, or 1.106 and 1.107; 10.302; or permission of instructor
Units: 3-8-4
______
Projects in applied energy engineering research. Students work in teams on one project for the term. Projects often suggested by local industry. Includes training in research planning and project management, execution of experimental work, data analysis, oral presentation skills and technical report writing, and team-building. Projects consider social science issues in addition to technical issues. Intended for students with diverse technical backgrounds. Preference to Energy Studies minors.
C. K. Colton, M. S. Strano, J. F. Hamel, W. A. Tisdale, G. Stephanopoulos

10.28 Chemical-Biological Engineering Laboratory
______

Undergrad (Fall)
Prereq: 5.310 or 10.702; 7.05 or 5.07; or permission of instructor
Units: 2-8-5
URL: http://web.mit.edu/10.28/www
Lecture: M3-5 (66-156) Lab: WF1-5 (66-0042)
______
Introduces the complete design of the bioprocess: from vector selection to production, separation, and characterization of recombinant products. Utilize concepts from many fields, such as, chemical and electrical engineering, and biology. Student teams work through parallel modules spanning microbial fermentation and animal cell culture. With the bioreactor at the core of the experiments, students study cell metabolism and biological pathways, kinetics of cell growth and product formation, oxygen mass transport, scale-up and techniques for the design of process control loops. Introduces novel bioreactors and powerful analytical instrumentation. Downstream processing and recombinant product purification also included. Enrollment limited.
J.-F. Hamel
No textbook information available

10.29 Biological Engineering Projects Laboratory
______

Undergrad (Spring)
(Subject meets with10.26,10.27)
Prereq: 2.671, 3.014, 5.310, 7.02, 12.335, or 1.106 and 1.107; 10.302; or permission of instructor
Units: 3-8-4
______
Projects in applied biological engineering research. Students work in teams on one project for the term. Projects often suggested by local industry. Includes training in research planning and project management, execution of experimental work, data analysis, oral presentation skills and report writing, and team-building.
C. K. Colton, J. F. Hamel, D. G. Anderson

10.291[J] Introduction to Sustainable Energy
______

Undergrad (Fall)
(Same subject as2.650[J],22.081[J])
(Subject meets with1.818[J],2.65[J],10.391[J],11.371[J],22.811[J])
Prereq: Permission of instructor
Units: 3-1-8
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various renewable and conventional energy production technologies, energy end-use practices and alternatives, and consumption practices in different countries. Investigates their attributes within a quantitative analytical framework for evaluation of energy technology system proposals. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments. Limited to juniors and seniors.
M. W. Golay
Textbooks (Fall 2016)

10.301 Fluid Mechanics
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: 18.03, 10.10
Units: 4-0-8
______
Introduces the mechanical principles governing fluid flow. Stress in a fluid. Conservation of mass and momentum, using differential and integral balances. Elementary constitutive equations. Hydrostatics. Exact solutions of the Navier-Stokes equations. Approximate solutions using control volume analysis. Mechanical energy balances and Bernoulli's equation. Dimensional analysis and dynamic similarity. Introduces boundary-layer theory and turbulence.
P. S. Doyle, F. R. Brushett

10.302 Transport Processes
______

Undergrad (Fall)
Prereq: 5.60, 10.301, 10.213; or permission of instructor
Units: 4-0-8
Lecture: MWF12 (66-110) Recitation: T11 (66-144) or T12 (66-144) +final
______
Principles of heat and mass transfer. Steady and transient conduction and diffusion. Radiative heat transfer. Convective transport of heat and mass in both laminar and turbulent flows. Emphasis on the development of a physical understanding of the underlying phenomena and upon the ability to solve real heat and mass transfer problems of engineering significance.
W. A. Tisdale, K. Chung
Textbooks (Fall 2016)

10.31 Nanoscale Energy Transport Processes
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with10.51)
Prereq: 10.302 or 2.51; 3.024, 5.61, or 6.007; or permission of instructor
Units: 3-0-9
______
Explores the impact of nanoscale phenomena on macroscale transport of energy-carrying molecules, phonons, electrons, and excitons. Studies the effect of structural and energetic disorder, wave-like vs. particle-like transport, quantum and classical size effects, and quantum coherence. Emphasizes quantitative analysis, including the Boltzmann transport equation, Einstein relation, Wiedemann-Franz law, and Marcus electron transfer theory. Also addresses percolation theory and the connection to energy conversion technologies, such as solar cells, thermoelectrics, and LEDs. Students taking graduate version complete additional assignments.
W. A. Tisdale

10.32 Separation Processes
______

Undergrad (Spring)
Prereq: 10.213, 10.302
Units: 2-0-4
______
General principles of separation by equilibrium and rate processes. Staged cascades. Applications to distillation, absorption, adsorption, and membrane processes. Use of material balances, phase equilibria, and diffusion to understand and design separation processes.
T. A. Hatton

10.333 Introduction to Modeling and Simulation
______

Undergrad (Spring) Rest Elec in Sci & Tech
Engineering School-Wide Elective Subject.
(Offered under:1.021,3.021,10.333,22.00)
Prereq: 18.03, 3.016, or permission of instructor
Units: 4-0-8
______
Basic concepts of computer modeling and simulation in science and engineering. Uses techniques and software for simulation, data analysis and visualization. Continuum, mesoscale, atomistic and quantum methods used to study fundamental and applied problems in physics, chemistry, materials science, mechanics, engineering, and biology. Examples drawn from the disciplines above are used to understand or characterize complex structures and materials, and complement experimental observations.
M. Buehler, R. Taylor

10.34 Numerical Methods Applied to Chemical Engineering
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
URL: http://web.mit.edu/10.34/www/
Lecture: MWF11 (66-110) +final
______
Numerical methods for solving problems arising in heat and mass transfer, fluid mechanics, chemical reaction engineering, and molecular simulation. Topics: numerical linear algebra, solution of nonlinear algebraic equations and ordinary differential equations, solution of partial differential equations (e.g. Navier-Stokes), numerical methods in molecular simulation (dynamics, geometry optimization). All methods are presented within the context of chemical engineering problems. Familiarity with structured programming is assumed.
W. H. Green, J. W. Swan
Textbooks (Fall 2016)

10.345 Fundamentals of Metabolic and Biochemical Engineering: Applications to Biomanufacturing
(New)
______

Undergrad (Spring)
(Subject meets with10.545)
Prereq: 5.07, 7.05, or permission of instructor
Units: 3-0-9
______
Examines the fundamentals of cell and metabolic engineering for biocatalyst design and optimization, as well as biochemical engineering principles for bioreactor design and operation, and downstream processing. Presents applications of microbial processes for production of commodity and specialty chemicals and biofuels in addition to mammalian cell cultures for production of biopharmaceuticals. Students taking graduate version complete additional assignments.
Gr. Stephanopoulos

10.37 Chemical Kinetics and Reactor Design
______

Undergrad (Spring)
Prereq: 5.60, 10.301
Units: 3-0-6
URL: http://web.mit.edu/10.37/www/
______
Applies the concepts of reaction rate, stoichiometry and equilibrium to the analysis of chemical and biological reacting systems. Derivation of rate expressions from reaction mechanisms and equilibrium or steady state assumptions. Design of chemical and biochemical reactors via synthesis of chemical kinetics, transport phenomena, and mass and energy balances. Topics: chemical/biochemical pathways; enzymatic, pathway and cell growth kinetics; batch, plug flow and well-stirred reactors for chemical reactions and cultivations of microorganisms and mammalian cells; heterogeneous and enzymatic catalysis; heat and mass transport in reactors, including diffusion to and within catalyst particles and cells or immoblized enzymes.
Gr. Stephanopoulos, Y. Roman

10.390[J] Fundamentals of Advanced Energy Conversion
______

Undergrad (Spring)
(Same subject as2.60[J])
(Subject meets with2.62[J],10.392[J],22.40[J])
Prereq: 2.006, or 2.051 and 2.06, or permission of instructor
Units: 4-0-8
______
Fundamentals of thermodynamics, chemistry, and transport applied to energy systems. Analysis of energy conversion and storage in thermal, mechanical, chemical, and electrochemical processes in power and transportation systems, with emphasis on efficiency, performance, and environmental impact. Applications to fuel reforming and alternative fuels, hydrogen, fuel cells and batteries, combustion, catalysis, combined and hybrid power cycles using fossil, nuclear and renewable resources. CO2 separation and capture. Biomass energy. Students taking graduate version complete additional assignments.
A. F. Ghoniem, W. Green

10.391[J] Sustainable Energy
______

Graduate (Fall)
(Same subject as1.818[J],2.65[J],11.371[J],22.811[J])
(Subject meets with2.650[J],10.291[J],22.081[J])
Prereq: Permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/10.391J/www/
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various energy technologies in each fuel cycle stage for fossil (oil, gas, synthetic), nuclear (fission and fusion) and renewable (solar, biomass, wind, hydro, and geothermal) energy types, along with storage, transmission, and conservation issues. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments.
M. W. Golay
Textbooks (Fall 2016)

10.392[J] Fundamentals of Advanced Energy Conversion
______

Graduate (Spring)
(Same subject as2.62[J],22.40[J])
(Subject meets with2.60[J],10.390[J])
Prereq: 2.006, or 2.051 and 2.06, or permission of instructor
Units: 4-0-8
______
Fundamentals of thermodynamics, chemistry, and transport applied to energy systems. Analysis of energy conversion and storage in thermal, mechanical, chemical, and electrochemical processes in power and transportation systems, with emphasis on efficiency, performance and environmental impact. Applications to fuel reforming and alternative fuels, hydrogen, fuel cells and batteries, combustion, catalysis, combined and hybrid power cycles using fossil, nuclear and renewable resources. CO2 separation and capture. Biomass energy. Meets with 2.60 when offered concurrently; students taking the graduate version complete additional assignments.
A. F. Ghoniem, W. Green

10.40 Chemical Engineering Thermodynamics
______

Graduate (Fall)
Prereq: 10.213
Units: 4-0-8
Lecture: TR9-11 (66-110) +final
______
Basic postulates of classical thermodynamics. Application to transient open and closed systems. Criteria of stability and equilibria. Constitutive property models of pure materials and mixtures emphasizing molecular-level effects using the formalism of statistical mechanics. Phase and chemical equilibria of multicomponent systems. Applications emphasized through extensive problem work relating to practical cases.
D. Blankschtein
Textbooks (Fall 2016)

10.407[J] Funding Strategies for Startups
______

Graduate (Spring); second half of term
(Same subject as2.916[J])
Prereq: None
Units: 2-0-4
______
Introduction to the substance and process of funding technology startups. Topics include a comparative analysis of various sources of capital; templates to identify the optimal investor; legal frameworks, US and offshore, of the investment process and its related jargon; an introduction to understanding venture capital as a business; and market practice and standards for term sheet negotiation. Emphasizes strategy as well as tactics necessary to negotiate and build effective, long-term relationships with investors, particularly venture capital firms (VCs).
S. Loessberg, D. P. Hart

10.424 Pharmaceutical Engineering
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with10.524)
Prereq: 10.213
Units: 3-0-6
______
Presents engineering principles and unit operations involved in the manufacture of small molecules pharmaceuticals, from the isolation of purified active pharmaceutical ingredients (API) to the final production of drug product. Regulatory issues include quality by design and process analytical technologies of unit operations, such as crystallization, filtration, drying, milling, blending, granulation, tableting and coating. Also covers principles of formulation for solid dosage forms and parenteral drugs. Students taking graduate version complete additional assignments. Limited to 50.
A. S. Myerson

10.426 Electrochemical Energy Systems
______

Undergrad (Spring)
(Subject meets with10.626)
Prereq: 10.302 or permission of instructor
Units: 3-0-9
______
Introduces principles and mathematical models of electrochemical energy conversion and storage. Studies equivalent circuits, thermodynamics, reaction kinetics, transport phenomena, electrostatics, porous media, and phase transformations. Includes applications to batteries, fuel cells, supercapacitors, and electrokinetics. Students taking graduate version complete additional assignments.
M. Z. Bazant

10.43 Introduction to Interfacial Phenomena
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 10.213 or introductory subject in thermodynamics or physical chemistry
Units: 3-0-6
______
Introduces fundamental and applied aspects of interfacial systems. Theory of capillarity. Experimental determination of surface and interfacial tensions. Thermodynamics of interfaces. The Gibbs adsorption equation. Charged interfaces. Surfactant adsorption at interfaces. Insoluble monolayers. Curvature effects on the equilibrium state of fluids. Nucleation and growth. Fundamentals of wetting and contact angle. Adhesion, cohesion, and spreading. Wetting of textured surfaces. Super-hydrophilic and super-hydrophobic surfaces. Self-cleaning surfaces.
D. Blankschtein

10.437[J] Quantum Chemical Simulation
______

Undergrad (Fall)
(Same subject as5.697[J])
(Subject meets with5.698[J],10.637[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (14-0637)
______
Addresses both the theory and application of first-principles computer simulations methods (i.e., quantum, chemical, or electronic structure), including Hartree-Fock theory, density functional theory, and correlated wavefunction methods. Covers enhanced sampling, ab initio molecular dynamics, and transition-path-finding approaches as well as errors and accuracy in total and free energies. Discusses applications such as the study and prediction of properties of chemical systems, including heterogeneous, molecular, and biological catalysts (enzymes), and physical properties of materials. Students taking graduate version complete additional assignments.
H. J. Kulik
Textbooks (Fall 2016)

10.441[J] Molecular and Engineering Aspects of Biotechnology
______

Undergrad (Spring)
(Same subject as7.37[J],20.361[J])
Prereq: 2.005, 3.012, 5.60, or 20.110; 7.06; or permission of instructor
Units: 4-0-8
Credit cannot also be received for7.371
URL: http://web.mit.edu/7.37j/
______
Covers biological and bioengineering principles underlying the development and therapeutic use of recombinant proteins and stem cells; glycoengineering of recombinant proteins; normal and pathological signaling by growth factors and their receptors; receptor trafficking; monoclonal antibodies as therapeutics; protein pharmacology and delivery; stem cell-derived tissues as therapeutics; RNA therapeutics; combinatorial protein engineering; and new antitumor drugs.
H. Lodish, L. Griffith

10.443 Future Medicine: Drug Delivery, Therapeutics, and Diagnostics
______

Undergrad (Spring)
(Subject meets with10.643[J],HST.526[J])
Prereq: 5.12 or permission of instructor
Units: 3-0-6
______
Aims to describe the direction and future of medical technology. Introduces pharmaceutics, pharmacology, and conventional medical devices, then transitions to drug delivery systems, mechanical/electric-based and biological/cell-based therapies, and sensors. Covers nano- and micro drug delivery systems, including polymer-drug conjugates, protein therapeutics, liposomes and polymer nanoparticles, viral and non-viral genetic therapy, and tissue engineering. Previous coursework in cell biology and organic chemistry recommended. Students taking graduate version complete additional assignments. Limited to 40.
D. G. Anderson

10.450 Process Dynamics, Operations, and Control
______

Undergrad (Spring)
Prereq: 10.302, 18.03
Units: 3-0-6
______
Introduction to dynamic processes and the engineering tasks of process operations and control. Subject covers modeling the static and dynamic behavior of processes; control strategies; design of feedback, feedforward, and other control structures; model-based control; applications to process equipment.
B. S. Johnston

10.466 Structure of Soft Matter
______

Not offered academic year 2017-2018Undergrad (Fall)
(Subject meets with10.566)
Prereq: 5.60
Units: 3-0-6
Lecture: MW9.30-11
______
Provides an introduction to the basic thermodynamic language used for describing the structure of materials, followed by a survey of the scattering, microscopy and spectroscopic techniques for structure and morphology characterization. Applies these concepts to a series of case studies illustrating the diverse structures formed in soft materials and the common length, time and energy scales that unify this field. For students interested in studying polymer science, colloid science, nanotechnology, biomaterials, and liquid crystals. Students taking graduate version complete additional assignments.
B. D. Olsen
No textbook information available

10.467 Polymer Science Laboratory
______

Undergrad (Fall)
Prereq: 5.12, 5.310
Units: 2-7-6
Lecture: MT1 (66-144) Lab: T2-5,R1-5 (E18-676)
______
Experiments broadly aimed at acquainting students with the range of properties of polymers, methods of synthesis, and physical chemistry. Examples: solution polymerization of acrylamide, bead polymerization of divinylbenzene, interfacial polymerization of nylon 6,10. Evaluation of networks by tensile and swelling experiments. Rheology of polymer solutions and suspensions. Physical properties of natural and silicone rubber. Preference to Course 10 seniors and juniors.
J. C. Love, D. G. Anderson
No textbook information available

10.489 Concepts in Modern Heterogeneous Catalysis
______

Undergrad (Spring)
Not offered regularly; consult department
(Subject meets with10.689)
Prereq: 10.37, 10.302
Units: 3-0-6
______
Explores topics in the design and implementation of heterogeneous catalysts for chemical transformations. Emphasizes use of catalysis for environmentally benign and sustainable chemical processes. Lectures address concepts in catalyst preparation, catalyst characterization, quantum chemical calculations, and microkinetic analysis of catalytic processes. Shows how experimental and theoretical approaches can illustrate important reactive intermediates and transition states involved in chemical reaction pathways, and uses that information to help identify possible new catalysts that may facilitate reactions of interest. Draws examples from current relevant topics in catalysis. Includes a group project in which students investigate a specific topic in greater depth. Students taking graduate version complete additional assignments.
Y. Roman

10.490 Integrated Chemical Engineering I
______

Undergrad (Fall); first half of term
Prereq: 10.37
Units: 3-0-5
Ends Nov 10. Lecture: MTRF10 (66-168) or MTRF11 (66-168)
______
Textbooks (Fall 2016)

10.491 Integrated Chemical Engineering II
______

Undergrad (Spring); first half of term
Prereq: 10.490
Units: 3-0-5
______
Presents and solves chemical engineering problems in an industrial context, with applications varying by term. Emphasis on the integration of fundamental concepts with approaches of process design. Emphasis on problems that demand synthesis, economic analysis, and process design.
P. I. Barton, B. S. Johnston

10.492 Integrated Chemical Engineering Topics I
______

Undergrad (Fall); second half of term
Prereq: 10.301 and permission of instructor
Units: 2-0-2
URL: http://web.mit.edu/cheme/
Begins Nov 14. Lecture: MTRF10 (66-168) or MTRF11 (66-168) or MTRF10 (66-160) or MTRF11 (66-160)
______
Chemical engineering problems presented and analyzed in an industrial context. Emphasizes the integration of fundamentals with material property estimation, process control, product development, and computer simulation. Integration of societal issues, such as engineering ethics, environmental and safety considerations, and impact of technology on society are addressed in the context of case studies. 10.37 and 10.302 required for certain topic modules. See departmental website for individual ICE-T module descriptions.
K. F. Jensen, Geo. Stephanopoulos
No required or recommended textbooks

10.493 Integrated Chemical Engineering Topics II
______

Undergrad (IAP)
Prereq: 10.301 and permission of instructor
Units: 2-0-2
URL: http://web.mit.edu/cheme/
______

10.494 Integrated Chemical Engineering Topics III
______

Undergrad (Spring)
Prereq: 10.301 and permission of instructor
Units: 2-0-2
URL: http://web.mit.edu/cheme/
______
Chemical engineering problems presented and analyzed in an industrial context. Emphasizes the integration of fundamentals with material property estimation, process control, product development, and computer simulation. Integration of societal issues, such as engineering ethics, environmental and safety considerations, and impact of technology on society are addressed in the context of case studies. 10.37 and 10.302 required for certain topic modules. See departmental website for individual ICE-T module descriptions.
K. F. Jensen, R. C. Armstrong

10.495 Molecular Design and Bioprocess Development of Immunotherapies
______

Undergrad (Spring)
(Subject meets with10.595)
Prereq: 7.06 or permission of instructor
Units: 3-0-6
______
Examines challenges and opportunities for applying chemical engineering principles to address the growing global burden of infectious disease, including drug-resistant strains and neglected pathogens. Topics include a historical overview of vaccines and immunotherapies, the molecular design considerations for new immunotherapies and adjuvants, the economic challenges for process development and manufacturing of immunotherapies, and new technologies for designing and assessing therapies. Case studies to cover topics for specific diseases. Students taking graduate version complete additional assignments.
J. C. Love

10.50 Analysis of Transport Phenomena
______

Graduate (Fall)
Prereq: 10.301, 10.302
Units: 4-0-8
Lecture: MWF1-2.30 (66-110) +final
______
Unified treatment of heat transfer, mass transfer, and fluid mechanics, emphasizing scaling concepts in formulating models and analytical methods for obtaining solutions. Topics include conduction and diffusion, laminar flow regimes, convective heat and mass transfer, and simultaneous heat and mass transfer with chemical reaction or phase change.
W. M. Deen, M. Z. Bazant
Textbooks (Fall 2016)

10.51 Nanoscale Energy Transport Processes
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with10.31)
Prereq: 10.302 or 2.51; 3.024, 5.61, or 6.007; or permission of instructor
Units: 3-0-9
______
Explores the impact of nanoscale phenomena on macroscale transport of energy-carrying molecules, phonons, electrons, and excitons. Studies the effect of structural and energetic disorder, wave-like vs. particle-like transport, quantum and classical size effects, and quantum coherence. Emphasizes quantitative analysis, including the Boltzmann transport equation, Einstein relation, Wiedemann-Franz law, and Marcus electron transfer theory. Also addresses percolation theory and the connection to energy conversion technologies, such as solar cells, thermoelectrics, and LEDs. Students taking graduate version complete additional assignments.
W. A. Tisdale

10.52 Mechanics of Fluids
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 10.50
Units: 3-0-6
______
Advanced subject in fluid and continuum mechanics. Content includes kinematics, macroscopic balances for linear and angular momentum, the stress tensor, creeping flows and the lubrication approximation, the boundary layer approximation, linear stability theory, and some simple turbulent flows.
Staff

10.524 Pharmaceutical Engineering
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with10.424)
Prereq: None
Units: 3-0-6
______
Presents engineering principles and unit operations involved in the manufacture of small molecules pharmaceuticals, from the isolation of purified active pharmaceutical ingredients (API) to the final production of drug product. Regulatory issues include quality by design and process analytical technologies of unit operations, such as crystallization, filtration, drying, milling, blending, granulation, tableting and coating. Also covers principles of formulation for solid dosage forms and parenteral drugs. Students taking graduate version complete additional assignments. Limited to 50.
A. S. Myerson

10.53[J] Advances in Biomanufacturing
______

Graduate (Fall, Spring); second half of term
(Same subject as7.548[J])
(Subject meets with 7.458[J],10.03[J])
Prereq: None
Units: 1-0-2
Begins Oct 24. Lecture: TR11 (66-148)
______
Seminar examines how biopharmaceuticals, an increasingly important class of pharmaceuticals, are manufactured. Topics range from fundamental bioprocesses to new technologies to the economics of biomanufacturing. Also covers the impact of globalization on regulation and quality approaches as well as supply chain integrity. Students taking graduate version complete additional assignments.
J. C. Love, A. Sinskey, S. Springs
No textbook information available

10.531[J] Macromolecular Hydrodynamics
______

Graduate (Spring)
(Same subject as2.341[J])
Prereq: 2.25, 10.301, or permission of instructor
Units: 3-0-6
______
Physical phenomena in polymeric liquids undergoing deformation and flow. Kinematics and material functions for complex fluids; techniques of viscometry, rheometry; and linear viscoelastic measurements for polymeric fluids. Generalized Newtonian fluids. Continuum mechnanics, frame invariance, and convected derivatives for finite strain viscoelasticity. Differential and integral constitutive equations for viscoelastic fluids. Analytical solutions to isothermal and non-isothermal flow problems; the roles of non-Newtonian viscosity, linear viscoelasticity, normal stresses, elastic recoil, stress relaxation in processing flows. Introduction to molecular theories for dynamics of polymeric fluids. (Extensive class project and presentation required instead of a final exam).
R. C. Armstrong, G. H. McKinley

10.536[J] Thermal Hydraulics in Power Technology
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as 2.59[J],22.313[J])
Prereq: 2.006, 10.302, 22.312, or permission of instructor
Units: 3-2-7
______
Emphasis on thermo-fluid dynamic phenomena and analysis methods for conventional and nuclear power stations. Kinematics and dynamics of two-phase flows. Steam separation. Boiling, instabilities, and critical conditions. Single-channel transient analysis. Multiple channels connected at plena. Loop analysis including single and two-phase natural circulation. Subchannel analysis.
E. Baglietto

10.537[J] Molecular, Cellular, and Tissue Biomechanics
______

Graduate (Fall)
(Same subject as2.798[J],3.971[J],6.524[J],20.410[J])
Prereq: Biology (GIR); 2.002, 2.006, 6.013, 10.301, or 10.302
Units: 3-0-9
Lecture: TR10.30-12 (2-143)
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, K. J. Van Vliet
No textbook information available

10.538[J] Biomolecular Kinetics and Cellular Dynamics
______

Graduate (Fall)
(Same subject as20.420[J])
Prereq: 7.06, 18.03
Units: 3-0-9
Lecture: TR9.30-11 +final
______
Fundamental analysis of biological rate processes using approaches from biomolecular reaction kinetics and dynamical systems engineering. Topics include binding and hybridization interactions, enzyme reactions, metabolic cycles, gene regulation, receptor/ligand trafficking systems, intra- and intercellular signaling, and cell population dynamics.
A. Jasanoff, E. Fraenkel
No textbook information available

10.539[J] Fields, Forces, and Flows in Biological Systems
______

Graduate (Fall)
(Same subject as2.795[J],6.561[J],20.430[J])
Prereq: 6.013, 2.005, 10.302, or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (32-124)
______
Molecular diffusion, diffusion-reaction, conduction, convection in biological systems; fields in heterogeneous media; electrical double layers; Maxwell stress tensor, electrical forces in physiological systems. Fluid and solid continua: equations of motion useful for porous, hydrated biological tissues. Case studies of membrane transport, electrode interfaces, electrical, mechanical, and chemical transduction in tissues, convective-diffusion/reaction, electrophoretic, electroosmotic flows in tissues/MEMs, and ECG. Electromechanical and physicochemical interactions in cells and biomaterials; musculoskeletal, cardiovascular, and other biological and clinical examples.
M. Bathe, A. J. Grodzinsky
Textbooks (Fall 2016)

10.540 Intracellular Dynamics
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 18.03, 7.06, 10.302, or permission of instructor
Units: 3-0-9
______
Covers current models and descriptions of the internal cell dynamics of macromolecules due to reaction and transport. Two major areas will be explored: the process of gene expression, including protein-DNA interactions, chromatin dynamics, and the stochastic nature of gene expression; and cell signaling systems, especially those that lead to or rely on intracellular protein gradients. This class is intended for graduate students or advanced undergraduates with some background in cell biology, transport, and kinetics. An introductory class in probability is recommended.
N. Maheshri

10.542 Biochemical Engineering
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
______
Interaction of chemical engineering, biochemistry, and microbiology. Mathematical representations of microbial systems. Kinetics of growth, death, and metabolism. Continuous fermentation, agitation, mass transfer, and scale-up in fermentation systems, enzyme technology.
K. J. Prather

10.544 Metabolic and Cell Engineering
______

Not offered academic year 2016-2017Graduate (Fall, Spring)
Prereq: 7.05, 10.302, 18.03
Units: 3-0-9
______
Presentation of a framework for quantitative understanding of cell functions as integrated molecular systems. Analysis of cell-level processes in terms of underlying molecular mechanisms based on thermodynamics, kinetics, mechanics, and transport principles, emphasizing an engineering, problem-oriented perspective. Objective is to rationalize target selection for genetic engineering and evaluate the physiology of recombinant cells. Topics include cell metabolism and energy production, transport across cell compartment barriers, protein synthesis and secretion, regulation of gene expression, transduction of signals from extracellular environment, cell proliferation, cell adhesion and migration.
Gr. Stephanopoulos

10.545 Fundamentals of Metabolic and Biochemical Engineering: Applications to Biomanufacturing
(New)
______

Graduate (Spring)
(Subject meets with10.345)
Prereq: 5.07, 7.05, or permission of instructor
Units: 3-0-9
______
Examines the fundamentals of cell and metabolic engineering for biocatalyst design and optimization, as well as biochemical engineering principles for bioreactor design and operation, and downstream processing. Presents applications of microbial processes for production of commodity and specialty chemicals and biofuels in addition to mammalian cell cultures for production of biopharmaceuticals. Students taking graduate version complete additional assignments.
Gr. Stephanopoulos

10.546[J] Statistical Thermodynamics
______

Graduate (Fall)
(Same subject as5.70[J])
Prereq: 5.60 or permission of instructor
Units: 3-0-9
Lecture: MW8.30-10 (4-231)
______
Develops classical equilibrium statistical mechanical concepts for application to chemical physics problems. Basic concepts of ensemble theory formulated on the basis of thermodynamic fluctuations. Examples of applications include Ising models, lattice models of binding, ionic and non-ionic solutions, liquid theory, polymer and protein conformations, phase transition, and pattern formation. Introduces computational techniques with examples of liquid and polymer simulations.
A. Willard, B. Zhang
Textbooks (Fall 2016)

10.547[J] Principles and Practice of Drug Development
______

Graduate (Fall)
(Same subject as7.547[J],15.136[J],HST.920[J],IDS.620[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://hst-hu-mit.mit.edu/courses/HST920
Lecture: W EVE (3-6 PM) (1-190)
______
Description and critical assessment of the major issues and stages of developing a pharmaceutical or biopharmaceutical. Drug discovery, preclinical development, clinical investigation, manufacturing and regulatory issues considered for small and large molecules. Economic and financial considerations of the drug development process. Multidisciplinary perspective from faculty in clinical; life; and management sciences; as well as industry guests.
T. J. Allen, C. L. Cooney, S. N. Finkelstein, A. J. Sinskey, G. K. Raju
No textbook information available

10.548[J] Tumor Pathophysiology and Transport Phenomena: A Systems Biology Approach
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject asHST.525[J])
Prereq: 18.03; 10.301
Units: 2-0-4
______
Tumor pathophysiology plays a central role in the growth, invasion, metastasis and treatment of solid tumors. Principles of transport phenomena are applied to develop a systems level, quantitative understanding of angiogenesis, blood flow and microcirculation, metabolism and microenvironment, transport and binding of small and large molecules, movement of cancer and immune cells, metastatic process, and treatment response.
R. K. Jain

10.55 Colloid and Surfactant Science
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
______
Introduces fundamental and applied aspects of colloidal dispersions, where the typical particle size is less than a micrometer. Discusses the characterization and unique behavior of colloidal dispersions, including their large surface-to-volume ratio, tendency to sediment in gravitational and centrifugal fields, diffusion characteristics, and ability to generate osmotic pressure and establish Donnan equilibrium. Covers the fundamentals of attractive van der Waals forces and repulsive electrostatic forces. Presents an in-depth discussion of electrostatic and polymer-induced colloid stabilization, including the DLVO theory of colloid stability. Presents an introductory discussion of surfactant physical chemistry.
D. Blankschtein

10.551 Systems Engineering
______

Graduate (Spring)
Prereq: 10.213, 10.302, 10.37
Units: 3-0-6
URL: http://web.mit.edu/10.551/www/
______
Introduction to the elements of systems engineering. Special attention devoted to those tools that help students structure and solve complex problems. Illustrative examples drawn from a broad variety of chemical engineering topics, including product development and design, process development and design, experimental and theoretical analysis of physico-chemical process, analysis of process operations.
Geo. Stephanopoulos, R. D. Braatz

10.552 Advanced Systems Engineering
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: None
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Covers modern methods for dynamical systems analysis, state estimation, controller design, and related topics. Uses example applications to demonstrate Lyapunov and linear matrix inequality-based methods that explicitly address actuator constraints, nonlinearities, and model uncertainties. Limited to 30.
R. D. Braatz

10.555[J] Bioinformatics: Principles, Methods and Applications
______

Graduate (Spring)
(Same subject asHST.940[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Introduction to bioinformatics, the collection of principles and computational methods used to upgrade the information content of biological data generated by genome sequencing, proteomics, and cell-wide physiological measurements of gene expression and metabolic fluxes. Fundamentals from systems theory presented to define modeling philosophies and simulation methodologies for the integration of genomic and physiological data in the analysis of complex biological processes. Various computational methods address a broad spectrum of problems in functional genomics and cell physiology. Application of bioinformatics to metabolic engineering, drug design, and biotechnology also discussed.
Gr. Stephanopoulos, I. Rigoutsos

10.557 Mixed-integer and Nonconvex Optimization
______

Graduate (Spring)
Prereq: 10.34 or 15.053
Units: 3-0-9
______
Presents the theory and practice of deterministic algorithms for locating the global solution of NP-hard optimization problems. Recurring themes and methods are convex relaxations, branch-and-bound, cutting planes, outer approximation and primal-relaxed dual approaches. Emphasis is placed on the connections between methods. These methods will be applied and illustrated in the development of algorithms for mixed-integer linear programs, mixed-integer convex programs, nonconvex programs, mixed-integer nonconvex programs, and programs with ordinary differential equations embedded. The broad range of engineering applications for these optimization formulations will also be emphasized. Students will be assessed on homework and a term project for which examples from own research are encouraged.
P. I. Barton

10.56 Advanced Topics in Surfactant Science
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
______
Introduces fundamental advances and practical aspects of surfactant self-assembly in aqueous media. In-depth discussion of surfactant micellization, including statistical-thermodynamics of micellar solutions, models of micellar growth, molecular models for the free energy of micellization, and geometric packing theories. Presents an introductory examination of mixed micelle and vesicle formation, polymer-surfactant complexation, biomolecule-surfactant interactions, and micellar-assisted solubilization. Discusses molecular dynamics simulations of self-assembling systems. Covers recent advances in surfactant-induced dispersion and stabilization of colloidal particles (e.g., carbon nanotubes and graphene) in aqueous media. Examines surfactant applications in consumer products, environmental and biological separations, enhanced oil recovery using surfactant flooding, mitigation of skin irritation induced by surfactant-containing cosmetic products, and enhanced transdermal drug delivery using ultrasound and surfactants.
D. Blankschtein

10.560 Structure and Properties of Polymers
______

Graduate (Spring)
Prereq: 10.213 or permission of instructor
Units: 3-0-6
______
Review of polymer molecular structure and bulk morphology; survey of molecular and morphological influence on bulk physical properties including non-Newtonian flow, macromolecular diffusion, gas transport in polymers, electrical and optical properties, solid-state deformation, and toughness. Case studies for product design.
R. E. Cohen

10.562[J] Imaging and Sample Processing in Biology and Medicine
______

Graduate (Spring)
(Same subject asHST.562[J])
Prereq: Biology (GIR), 5.12; or permission of instructor
Units: 3-1-8
______
Discusses basic principles and concepts of bioimaging and sample processing. Topics include optical imaging modalities; optical/physical/chemical properties of a broad range of biological samples, including clinical tissues and sample handling/processing technologies; underlying engineering principles; and basic image analysis. Provides experience with optical microscopy and tissue processing technique (CLARITY). Limited to 15.
K. Chung

10.566 Structure of Soft Matter
______

Not offered academic year 2017-2018Graduate (Fall)
(Subject meets with10.466)
Prereq: 5.60
Units: 3-0-6
Lecture: MW9.30-11
______
Provides an introduction to the basic thermodynamic language used for describing the structure of materials, followed by a survey of the scattering, microscopy and spectroscopic techniques for structure and morphology characterization. Applies these concepts to a series of case studies illustrating the diverse structures formed in soft materials and the common length, time and energy scales that unify this field. For students interested in studying polymer science, colloid science, nanotechnology, biomaterials, and liquid crystals. Students taking graduate version complete additional assignments.
B. D. Olsen
No textbook information available

10.568 Physical Chemistry of Polymers
______

Graduate (Fall, Spring)
Prereq: 5.60, 10.213, or 10.40
Units: 3-0-6
Lecture: TR11-12.30 (66-154)
______
Chain macromolecules as random coils (unperturbed, expanded) and as other shapes. Statistical thermodynamics of interpenetrating random coiling polymers in solution with application to phase separations, swelling of networks, depression of melting point. The isolated chain molecule in dilute solutions analyzed for mass or size by static methods (osmometry, light scattering, neutron scattering) and by dynamic methods (intrinsic viscosity, size exclusion chromatography, sedimentation). Introduction to chain dynamics and to rubber elasticity.
R. E. Cohen
Textbooks (Fall 2016)

10.569 Synthesis of Polymers
______

Graduate (Spring)
Prereq: 5.12
Units: 3-0-6
______
Studies synthesis of polymeric materials, emphasizing interrelationships of chemical pathways, process conditions, and microarchitecture of molecules produced. Chemical pathways include traditional approaches such as anionic, radical condensation, and ring-opening polymerizations. New techniques, including stable free radicals and atom transfer free radicals, new catalytic approaches to well-defined architectures, and polymer functionalization in bulk and at surfaces. Process conditions include bulk, solution, emulsion, suspension, gas phase, and batch vs continuous fluidized bed. Microarchitecture includes tacticity, molecular-weight distribution, sequence distributions in copolymers, errors in chains such as branches, head-to-head addition, and peroxide incorporation.
P. T. Hammond, B. D. Olsen

10.571[J] Atmospheric Physics and Chemistry
______

Graduate (Spring)
(Same subject as12.806[J])
(Subject meets with12.306)
Prereq: 5.60 or 5.61; 18.075; or permission of instructor
Units: 3-0-9
______
Introduction to the physics and chemistry of the atmosphere including experience with computer codes. Aerosols and theories of their formation, evolution, and removal. Gas and aerosol transport from urban to continental scales. Coupled models of radiation, transport, and chemistry. Solution of inverse problems to deduce emissions and removal rates. Emissions control technology and costs. Applications to air pollution and climate.
R. G. Prinn

10.579[J] Energy Technology and Policy: From Principles to Practice
______

Graduate (Spring)
(Same subject as5.00[J],6.929[J],22.813[J])
Prereq: None
Units: 3-0-6
______
Develops analytical skills to lead a successful technology implementation with an integrated approach that combines technical, economical and social perspectives. Considers corporate and government viewpoints as well as international aspects, such as nuclear weapons proliferation and global climate issues. Discusses technologies such as oil and gas, nuclear, solar, and energy efficiency. Limited to 100.
J. Deutch

10.580 Solid-State Surface Science
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 10.213
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Structural, chemical, and electronic properties of solids and solid surfaces. Analytical tools used to characterize surfaces including Auger and photoelectron spectroscopies and electron diffraction techniques. Surface thermodynamics and kinetics including adsorption-desorption, catalytic properties, and sputtering processes. Applications to microelectronics, optical materials, and catalysis.
K. K. Gleason

10.585 Engineering Nanotechnology
______

Graduate (Fall)
Prereq: 10.302, 10.213, or permission of instructor
Units: 3-0-9
Lecture: TR12.30-2 (66-110)
______
Review of fundamental concepts of energy, mass and electron transport in materials confined or geometrically patterned at the nanoscale, where departures from classical laws are dominant. Specific applications to contemporary engineering challenges are discussed including problems in energy, biology, medicine, electronics, and material design.
M. Strano
No textbook information available

10.586 Crystallization Science and Technology
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 10.213
Units: 3-0-6
Lecture: TR11-12.30 (56-169)
______
Studies the nucleation and growth of crystals from a melt or a liquid solution and their important role in a wide range of applications, including pharmaeuticals, proteins, and semiconductor materials. Provides background information and covers topics needed to understand, perform experiments, construct and simulate mechanistic models, and design, monitor, and control crystallization processes. Limited to 30.
A. S. Myerson
No required or recommended textbooks

10.591 Case Studies in Bioengineering
______

Graduate (Fall)
Prereq: Biology (GIR) or permission of instructor
Units: 3-0-6
Lecture: T EVE (4-6 PM) (66-148) Recitation: W EVE (5 PM) (66-148)
______
Analysis and discussion of recent research in areas of bioengineering, including drug delivery, protein and tissue engineering, physiological transport, stem cell technology, and quantitative immunology by senior investigators in the Boston area. Students will read and critique papers, then have discussions with authors about their work.
C. K. Colton
No required or recommended textbooks

10.595 Molecular Design and Bioprocess Development of Immunotherapies
______

Graduate (Spring)
(Subject meets with10.495)
Prereq: Permission of instructor
Units: 3-0-6
______
Examines challenges and opportunities for applying chemical engineering principles to address the growing global burden of infectious disease, including drug-resistant strains and neglected pathogens. Topics include a historical overview of vaccines and immunotherapies, the molecular design considerations for new immunotherapies and adjuvants, the economic challenges for process development and manufacturing of immunotherapies, and new technologies for designing and assessing therapies. Case studies to cover topics for specific diseases. Students taking graduate version complete additional assignments.
J. C. Love

10.606 Visual Strategies for Scientists and Engineers
______

Graduate (Spring); first half of term
Prereq: None
Units: 1-2-2 [P/D/F]
______
Provides instruction in best practices for creating more effective graphics and photographs to support and communicate research in science and engineering. Discusses in depth specific examples from a range of scientific contexts, such as journal articles, presentations, grant submissions, and cover art. Topics include graphics for figures depicting form and structure, process, and change over time. Prepares students to create effective graphics for submissions to existing journals and calls attention to the future of published graphics with the advent of interactivity. Limited to 10.
F. Frankel

10.625[J] Electrochemical Energy Conversion and Storage: Fundamentals, Materials and Applications
______

Graduate (Fall)
(Same subject as2.625[J])
Prereq: 2.005, 3.046, 3.53, 10.40, or 2.051 and 2.06, or permission of instructor
Units: 4-0-8
Lecture: TR2.30-4 (3-333) Recitation: W4 (1-150)
______
Fundamental concepts, tools, and applications in electrochemical science and engineering. Introduces thermodynamics, kinetics and transport of electrochemical reactions. Describes how materials structure and properties affect electrochemical behavior of particular applications, for instance in lithium rechargeable batteries, electrochemical capacitors, fuel cells, photo electrochemical cells, and electrolytic cells. Discusses state-of-the-art electrochemical energy technologies for portable electronic devices, hybrid and plug-in vehicles, electrical vehicles. Theoretical and experimental exploration of electrochemical measurement techniques in cell testing, and in bulk and interfacial transport measurements (electronic and ionic resistivity and charge transfer cross the electrode-electrolyte interface).
Y. Shao-Horn
No textbook information available

10.626 Electrochemical Energy Systems
______

Graduate (Spring)
(Subject meets with10.426)
Prereq: 10.50 or permission of instructor
Units: 3-0-9
______
Introduces principles and mathematical models of electrochemical energy conversion and storage. Studies equivalent circuits, thermodynamics, reaction kinetics, transport phenomena, electrostatics, porous media, and phase transformations. Includes applications to batteries, fuel cells, supercapacitors, and electrokinetics. Students taking graduate version complete additional assignments.
M. Z. Bazant

10.631 Structural Theories of Polymer Fluid Mechanics
______

Graduate (Spring)
Prereq: 10.301
Units: 3-0-6
______
Structural and molecular models for polymeric liquids. Nonequilibrium properties are emphasized. Elementary kinetic theory of polymer solutions. General phase space kinetic for polymer melts and solutions. Network theories. Interrelations between structure and rheological properties.
R. C. Armstrong

10.637[J] Quantum Chemical Simulation
______

Graduate (Fall)
(Same subject as5.698[J])
(Subject meets with5.697[J],10.437[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (14-0637)
______
Addresses both the theory and application of first-principles computer simulations methods (i.e., quantum, chemical, or electronic structure), including Hartree-Fock theory, density functional theory, and correlated wavefunction methods. Covers enhanced sampling, ab initio molecular dynamics, and transition-path-finding approaches as well as errors and accuracy in total and free energies. Discusses applications such as the study and prediction of properties of chemical systems, including heterogeneous, molecular, and biological catalysts (enzymes), and physical properties of materials. Students taking graduate version complete additional assignments.
H. J. Kulik
Textbooks (Fall 2016)

10.643[J] Future Medicine: Drug Delivery, Therapeutics, and Diagnostics
______

Graduate (Spring)
(Same subject asHST.526[J])
(Subject meets with10.443)
Prereq: 5.12 or permission of instructor
Units: 3-0-6
______
Aims to describe the direction and future of medical technology. Introduces pharmaceutics, pharmacology, and conventional medical devices, then transitions to drug delivery systems, mechanical/electric-based and biological/cell-based therapies, and sensors. Covers nano- and micro drug delivery systems, including polymer-drug conjugates, protein therapeutics, liposomes and polymer nanoparticles, viral and non-viral genetic therapy, and tissue engineering. Previous coursework in cell biology and organic chemistry recommended. Students taking graduate version complete additional assignments. Limited to 40.
D. G. Anderson

10.644[J] Frontiers in Therapeutics and Drug Delivery
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject asHST.914[J])
Prereq: 7.05 or permission of instructor
Units: 3-0-6
______
Provides an introduction to pharmaceutics and conventional oral, injected, transdermal and inhaled drug delivery systems. Includes studies of drug delivery devices and systems, e.g., stents, pumps, depo systems, responsive drug delivery systems, and biological/cell based therapies. Covers nano- and micro drug delivery systems, including polymer-drug conjugates, modified proteins, liposomes and polymer nanoparticles, viral and non-viral genetic therapy, and microencapsulated vaccines. Discusses reviews and current technology. Students taking graduate version complete additional assignments. Limited to 40.
D. G. Anderson

10.65 Chemical Reactor Engineering
______

Graduate (Spring)
Prereq: 10.37 or permission of instructor
Units: 4-0-8
URL: https://web.mit.edu/10.65/www/
______
Fundamentals of chemically reacting systems with emphasis on synthesis of chemical kinetics and transport phenomena. Topics include kinetics of gas, liquid, and surface reactions; quantum chemistry; transition state theory; surface adsorption, diffusion, and desorption processes; mechanism and kinetics of biological processes; mechanism formulation and sensitivity analysis. Reactor topics include nonideal flow reactors, residence time distribution and dispersion models; multiphase reaction systems; nonlinear reactor phenomena. Examples are drawn from different applications, including heterogeneous catalysis, polymerization, combustion, biochemical systems, and materials processing.
M. Strano, G. Stephanopoulos

10.652[J] Kinetics of Chemical Reactions
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as5.68[J])
Prereq: 5.62, 10.37, or 10.65
Units: 3-0-6
URL: http://web.mit.edu/10.652/www/
Lecture: TR11-12.30 (56-114)
______
Experimental and theoretical aspects of chemical reaction kinetics, including transition-state theories, molecular beam scattering, classical techniques, quantum and statistical mechanical estimation of rate constants, pressure-dependence and chemical activation, modeling complex reacting mixtures, and uncertainty/ sensitivity analyses. Reactions in the gas phase, liquid phase, and on surfaces are discussed with examples drawn from atmospheric, combustion, industrial, catalytic, and biological chemistry.
W. H. Green
Textbooks (Fall 2016)

10.668[J] Statistical Mechanics of Polymers
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as3.941[J])
Prereq: 10.568 or permission of instructor
Units: 3-0-9
______
Concepts of statistical mechanics and thermodynamics applied to macromolecules: polymer conformations in melts, solutions, and gels; Rotational Isomeric State theory, Markov processes and molecular simulation methods applied to polymers; incompatibility and segregation in incompressible and compressible systems; molecular theory of viscoelasticity; relation to scattering and experimental measurements.
G. C. Rutledge, A. Alexander-Katz

10.677 Topics in Applied Microfluidics
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 10.301 or permission of instructor.
Units: 3-0-6
______
Provides an introduction to the field of microfluidics. Reviews fundamental concepts in transport phenomena and dimensional analysis, focusing on new phenomena which arise at small scales. Discusses current applications, with an emphasis on the contributions engineers bring to the field. Local and visiting experts in the field discuss their work. Limited to 30.
P. Doyle

10.689 Concepts in Modern Heterogeneous Catalysis
______

Graduate (Spring)
Not offered regularly; consult department
(Subject meets with10.489)
Prereq: 10.37, 10.302
Units: 3-0-6
______
Explores topics in the design and implementation of heterogeneous catalysts for chemical transformations. Emphasizes use of catalysis for environmentally benign and sustainable chemical processes. Lectures address concepts in catalyst preparation, catalyst characterization, quantum chemical calculations, and microkinetic analysis of catalytic processes. Shows how experimental and theoretical approaches can illustrate important reactive intermediates and transition states involved in chemical reaction pathways, and uses that information to help identify possible new catalysts that may facilitate reactions of interest. Draws examples from current relevant topics in catalysis. Includes a group project in which students investigate a specific topic in greater depth. Students taking graduate version complete additional assignments.
Y. Roman

10.702[J] Introduction to Experimental Biology and Communication
______

Undergrad (Fall, Spring) Institute Lab
(Same subject as7.02[J])
Prereq: Biology (GIR)
Units: 4-8-6
1st mtg 9/8 mandatory. Lecture: TR11 (32-155) Lab: TR1-5 (68-074) or WF1-5 (68-074) Recitation: M9-11 (68-121) or M1-3 (66-148, 4-146) or T9-11 (4-144) or W1-3 (68-121) or W9-11 (68-121) +final
______
Introduction to the experimental concepts and methods of molecular biology, biochemistry, and genetic analysis. Emphasis on experimental design, critical data analysis, and the development of written communications skills. 12 units may be applied to the General Institute Laboratory Requirement. Concurrent registration with 7.03 strongly recommended. Enrollment limited.
Fall:T. Baker, M. Gehring, K. D. Wittrup
Spring:T. Baker, O. Yilmaz, K. D. Wittrup
No required or recommended textbooks

10.792[J] Global Operations Leadership Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as2.890[J],15.792[J],16.985[J])
Prereq: None
Units arranged [P/D/F]
Lecture: M EVE (4-6 PM) (E62-262)
______
Integrative forum in which worldwide leaders in business, finance, government, sports, and education share their experiences and insights with students aspiring to run global operations. Students play a large role in managing the seminar. Preference to LGO students.
T. Roemer
No textbook information available

10.805[J] Technology, Law, and the Working Environment
(New)
______

Graduate (Spring)
Not offered regularly; consult department
(Same subject asIDS.436[J])
(Subject meets with1.802[J],1.812[J],11.022[J],11.631[J],IDS.431[J])
Prereq: Permission of instructor
Units: 3-0-6
______
Addresses relationship between technology-related problems and the law applicable to work environment. National Labor Relations Act, Occupational Safety and Health Act. Toxic Substances Control Act, state worker's compensation, and suits by workers in the courts discussed. Problems related to occupational health and safety, collective bargaining as a mechanism for altering technology in the workplace, job alienation, productivity, and the organization of work addressed. Prior courses or experience in the environmental, public health, or law-related areas.
N. A. Ashford, C. C. Caldart

10.806 Management in Engineering
______

Undergrad (Fall)
Engineering School-Wide Elective Subject.
(Offered under:2.96,6.930,10.806,16.653)
Prereq: None
Units: 3-1-8
Lecture: MW11-12.30 (35-225) Lab: M4 (35-308) or T10 (1-273) or R4 (1-371) or F1 (1-132) or F2 (1-132)
______
Introduction and overview of engineering management. Financial principles, management of innovation, technical strategy and best management practices. Case study method of instruction emphasizes participation in class discussion. Focus is on the development of individual skills and management tools. Restricted to juniors and seniors.
H. S. Marcus, J.-H. Chun
No textbook information available

10.807[J] Innovation Teams
______

Graduate (Fall, Spring)
(Same subject as15.371[J])
Prereq: 15.911 or permission of instructor
Units: 4-4-4
Lecture: W11-2 (32-144) Lab: F9-11.30 (32-155)
______
Students work in teams to develop commercialization strategies for innovative research projects generated in MIT laboratories. Projects cover critical aspects of commercialization, from selecting the target application and market for the technology to developing an intellectual property strategy and performing a competitive analysis. Instruction provided in communication and teamwork skills, as well as analysis of the challenges and benefits of technology transfer. Includes lectures, guest speakers, and extensive team coaching. Designed primarily for students in engineering, science, and management. Applications, resumes, and a brief statement of interest are required prior to registration.
F. Murray, L. Perez-Breva, N. Afeyan
No textbook information available

10.817[J] Atmospheric Chemistry
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as1.84[J],12.807[J])
Prereq: 5.60
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Provides a detailed overview of the chemical transformations that control the abundances of key trace species in the Earth's atmosphere. Emphasizes the effects of human activity on air quality and climate. Topics include photochemistry, kinetics, and thermodynamics important to the chemistry of the atmosphere; stratospheric ozone depletion; oxidation chemistry of the troposphere; photochemical smog; aerosol chemistry; and sources and sinks of greenhouse gases and other climate forcers.
J. H. Kroll

School of Chemical Engineering Practice

10.80 (10.82, 10.84, 10.86) School of Chemical Engineering Practice -- Technical Accomplishment
______

Graduate (Fall, Spring, Summer)
Prereq: None
Units: 0-6-0
10.80: TBA.
10.82: TBA.
10.84: TBA.
10.86: TBA.
______
Conducted at industrial field stations of the School of Chemical Engineering Practice. Group problem assignments include process development design, simulation and control, technical service, and new-product development. Grading based on technical accomplishment. Credit granted in lieu of master's thesis. See departmental descripton on School of Chemical Engineering Practice for details. Enrollment limited and subject to plant availability.
T. A. Hatton
10.80: No textbook information available
10.82: No textbook information available
10.84: No textbook information available
10.86: No textbook information available

10.81 (10.83, 10.85, 10.87) School of Chemical Engineering Practice -- Communication Skills and Human Relations
______

Graduate (Fall, Spring, Summer)
Prereq: None
Units: 0-6-0
10.81: TBA.
10.83: TBA.
10.85: TBA.
10.87: TBA.
______
Conducted at industrial field stations of the School of Chemical Engineering Practice. Group problem assignments include process development, design, simulation and control, technical service, and new-product development. Grading based on communication skills and human relations in group assignments. Credit granted in lieu of master's thesis; see departmental description on School of Chemical Engineering Practice for details. Enrollment limited and subject to plant availability.
T. A. Hatton
10.81: No textbook information available
10.83: No textbook information available
10.85: No textbook information available
10.87: No textbook information available


left arrow|10.00-10.899|10.90-10.999 plus THG, THU, UROP, UPOP|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 10: Chemical Engineering
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Course 10: Chemical Engineering
Fall 2016


General

10.90 Independent Research Problem
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
For special and graduate students who wish to carry out some minor investigation in a particular field. Subject and hours to fit individual requirements.
R. D. Braatz
No textbook information available

10.910 Independent Research Problem
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No textbook information available

10.911 Independent Research Problem
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
For undergraduate students who wish to carry out a special investigation in a particular field. Topic and hours arranged.
B. S. Johnston
No textbook information available

10.953 Seminar in Heterogeneous Catalysis
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: R12-2 (E17-517)
______
Students present their research to other students and staff. Research topics include heterogeneous catalysis, design of catalytic materials, biomass conversion, biofuels, and CO2 utilization.
Y. Roman
No required or recommended textbooks

10.954 Seminar in Applied Optical Spectroscopy
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: T2-4 (66-360)
______
Research seminars given by students, postdocs, and visitors. Topics covered include applied optical spectroscopy and imaging, with particular emphasis on nanomaterials and how they relate to alternative energy technologies.
W. A. Tisdale
No required or recommended textbooks

10.955 Seminar in Electrochemical Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: R EVE (4-6 PM) (66-360)
______
Designed to allow students to present and discuss their research in the area of electrochemical engineering with a particular emphasis on energy storage and conversion (e.g., batteries, fuel cells, electroreactors). Specific topics include active materials design, electroanalytical platform development, and integration of electrochemical and imaging techniques.
F. R. Brushett
No required or recommended textbooks

10.956 Seminar in Atomistic Simulation
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W3-5 (66-269)
______
Seminar allows students to present their research to other students and staff. The research topics include electronic structure theory, computational chemistry techniques, and density functional theory with a focus on applications to catalysis and materials science.
H. J. Kulik
No required or recommended textbooks

10.957 Seminar in Bioengineering Technology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W9-11 (46-5305)
______
Research seminars presented by students and guest speakers on emerging biotechnologies.
K. Chung
No required or recommended textbooks

10.958 Seminar in the Fluid Mechanics and Self-assembly of Soft Matter
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: M EVE (4-6 PM) (66-319)
______
Covers topics related to low Reynolds number hydrodynamics and the statistical physics of particulate media. Specifics include the kinetics of phase transitions in soft matter and the time-varying deformation of colloidal dispersions, glasses and gels.
J. W. Swan
No required or recommended textbooks

10.960[J] Seminar in Polymers and Soft Matter
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as3.903[J])
Prereq: None
Units: 2-0-0 [P/D/F]
Lecture: W3-5 (56-114)
______
A series of seminars covering a broad spectrum of topics in polymer science and engineering, featuring both on- and off-campus speakers.
A. Alexander-Katz, R. E. Cohen, D. Irvine
No required or recommended textbooks

10.961 Seminar in Advanced Air Pollution Research
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
______
Research seminars, presented by students engaged in thesis work in the field of air pollution. Particular emphasis given to atmospheric chemistry, mathematical modeling, and policy analysis.
G. J. McRae

10.962 Seminar in Molecular Cell Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: TR9.30-11
______
Weekly seminar with discussion of ongoing research and relevant literature by graduate students, postdoctoral fellows, and visiting scientists on issues at the interface of chemical engineering with molecular cell biology. Emphasis is on quantitative aspects of physicochemical mechanisms involved in receptor/ligand interactions, receptor signal transduction processes, receptor-mediated cell behavioral responses, and applications of these in biotechnology and medicine.
D. A. Lauffenburger
No required or recommended textbooks

10.964 Seminar on Transport Theory
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Class begins at 12:15. Lecture: M12-2.30 (66-360)
______
Research seminars presented by students and guest speakers on mathematical modeling of transport phenomena, focusing on electrochemical systems, electrokinetics, and microfluidics.
M. Z. Bazant
No required or recommended textbooks

10.965 Seminar in Biosystems Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: T9-11 (76-258)
______
Advanced topics on the state-of-the-art in design and implementation of analytical processes for biological systems, including single-cell analysis, micro/nanotechnologies, systems biology, biomanufacturing, and process engineering. Seminars and discussions guided by the research interests of participating graduate students, postdoctoral associates, faculty, and visiting lecturers.
J. C. Love
No required or recommended textbooks

10.966 Seminar in Drug Delivery, Biomaterials, and Tissue Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W12-2 (76-659)
______
Focuses on presentations by students and staff on current research in the area of drug delivery, biomaterials, and tissue engineering. Includes topics such as nanotherapeutics, intracellular delivery, and therapies for diabetes.
D. G. Anderson
No required or recommended textbooks

10.967 Seminar in Protein-Polymer Materials Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: F9-11 (66-319)
______
Research seminar covers topics on protein-based polymeric materials. Specific topics include bioelectronic materials, protein-polymer hybrids, and nanostructured proteins and polymers.
B. D. Olsen
No required or recommended textbooks

10.968 Seminar in Biomolecular Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W9-11 (E17-517)
______
Covers research progress in the area of design, testing and mechanistic investigation of novel molecular systems for biotechnological applications.
H. D. Sikes
No required or recommended textbooks

10.969 Molecular Engineering Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W2-4 (E17-517)
______
Seminar allows students to present their research to other students and staff. Research topics include molecular simulations techniques and applications, and molecular engineering of pharmaceutical and biopharmaceutical processes and formulations.
B. L. Trout
No required or recommended textbooks

10.970 Seminar in Molecular Computation
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W12-2 (E17-517)
______
Seminar allows students to present their research to other students and staff. The research topics include computational chemistry techniques, kinetics, and catalysis. Focus is on molecular-level understanding of chemical change.
W. H. Green
No required or recommended textbooks

10.971 Seminar in Fluid Mechanics and Transport Phenomena
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: R EVE (4-6 PM) (E17-517)
______
Seminar series on current research on Newtonian and non-Newtonian fluid mechanics and transport phenomena, and applications to materials processing. Seminars given by guest speakers and research students.
P. S. Doyle, G. H. McKinley, J. W. Swan
No required or recommended textbooks

10.972 Biochemical Engineering Research Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
______
Seminar allows students to present their research programs to other students and staff. The research topics include fermentation and enzyme technology, mammalian and animal cell cultivation, and biological product separation.
D. I. C. Wang, C. L. Cooney

10.973 Bioengineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: F1-3 (66-480)
______
Seminar covering topics related to current research in the application of chemical engineering principles to biomedical science and biotechnology.
C. K. Colton
No required or recommended textbooks

10.974 Seminar in Chemical Engineering Nanotechnology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: R EVE (5.30-7.30 PM) (66-110)
______
Seminar covering topics related to current research in the application of chemical engineering principles to nanotechnology. Limited to 30.
M. S. Strano
No required or recommended textbooks

10.975 Seminar in Polymer Science and Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: T12-2 (76-559) or T12.30-2.30 (E17-517) or T12-2 (66-360)
______
Research seminars, presented by students engaged in thesis work in the field of polymers and by visiting lecturers from industry and academia.
R. E. Cohen, P. T. Hammond, G. C. Rutledge
No required or recommended textbooks

10.976 Process Design, Operations, and Control
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: R4-5.30 (66-319)
______
Seminars on the state of the art in design, operations, and control of processing systems, with emphasis on computer-based tools. Discussions guided by the research interests of participating students. Topics include mathematical and numerical techniques, representational methodologies, and software development.
P. I. Barton
No required or recommended textbooks

10.981 Seminar in Colloid and Interface Science
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W3.30-5.30 (66-480)
______
Review of current topics in colloid and interface science. Topics include statistical mechanics and thermodynamics of micellar solutions, self-assembling systems, and microemulsions; solubilization of simple ions, amino acids, and proteins in reversed micelles; enzymatic reactions in reversed micelles; phase equilibria in colloidal systems; interfacial phenomena in colloidal systems; biomedical aspects of colloidal systems.
D. Blankschtein
No required or recommended textbooks

10.982 Seminar in Experimental Colloid and Surface Chemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: T EVE (4-6 PM) (66-360)
______
In-depth discussion of fundamental physical relationships underlying techniques commonly used in the study of colloids and surfaces with a focus on recent advances and experimental applications. Topics have included the application of steady-state and time-resolved fluorescence spectroscopies, infrared spectroscopy, and scanning probe microscopies.
T. A. Hatton
No required or recommended textbooks

10.983 Reactive Processing and Microfabricated Chemical Systems
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W EVE (4-6 PM) (66-360)
______
Advanced topics in synthesis of materials through processes involving transport phenomena and chemical reactions. Chemical vapor deposition, modeling, and experimental approaches to kinetics of gas phase and surface reactions, transport phenomena in complex systems, materials synthesis, and materials characterization. Design fabrication and applications of microfabricated chemical systems. Seminars by graduate students, postdoctoral associates, participating faculty, and visiting lecturers.
K. F. Jensen
No required or recommended textbooks

10.984 Biomedical Applications of Chemical Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W EVE (5-6.30 PM) (76-156)
______
Weekly seminar with lectures on current research by graduate students, postdoctoral fellows, and visiting scientists on topics related to biomedical applications of chemical engineering. Specific topics include polymeric controlled release technology, extracorporal reactor design, biomedical polymers, bioengineering aspects of pharmaceuticals, and biomaterials/tissue and cell interactions.
R. S. Langer
No required or recommended textbooks

10.985 Seminar in Materials Systems Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: M12 (E17-517)
______
Focuses on the state of the art in the systems engineering of materials products and materials manufacturing processes. Addresses topics such as pharmaceuticals manufacturing, polymeric drug delivery systems, and nano- and microstructured materials. Discussions guided by the research interests of participating students. Includes techniques from applied mathematics and numerical methods, multiscale systems analysis, and control theory.
R. D. Braatz
No required or recommended textbooks

10.987 Solid Thin Films and Interfaces
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: W2.30-4 (66-360)
______
Current research topics and fundamental issues relating to the deposition and properties of solid thin films and interfaces. Emphasis on applying analytical techniques, such as solid-state NMR, to explore the thermodynamics and kinetics of growth, defect formation, and structural modification incurred during film growth and post processing.
K. K. Gleason
No required or recommended textbooks

10.989 Seminar in Biotechnology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: R12-2 (66-360)
______
Research seminars, presented by graduate students and visitors from industry and academia, covering a broad range of topics of current interest in biotechnology. Discussion focuses on generic questions with potential biotechnological applications and the quest for solutions through a coordinated interdisciplinary approach.
Gr. Stephanopoulos
No required or recommended textbooks

10.990 Introduction to Chemical Engineering Research
______

Graduate (Fall)
Prereq: None
Units: 2-4-0 [P/D/F]
Lecture: TR2 (66-110) Lab: W3 (66-110)
______
Introduction to research in chemical engineering by faculty of chemical engineering department. Focus is on recent developments and research projects available to new graduate students.
P. T. Hammond, P. S. Doyle
No required or recommended textbooks

10.991 Seminar in Chemical Engineering
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: MF3-4.30 (66-110)
______
No required or recommended textbooks

10.992 Seminar in Chemical Engineering
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
______
For students working on doctoral theses.
K. F. Jensen

10.994 Molecular Bioengineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: R12-1.30 (76-261D)
______
Presentations and discussion by graduate students, postdoctoral fellows, and visiting scientists of current literature and research on the engineering of protein biopharmaceuticals. Topics include combinatorial library construction and screening strategies, antibody engineering, gene therapy, cytokine engineering, and immunotherapy engineering strategies.
K. D. Wittrup
No required or recommended textbooks

10.995 Cellular and Metabolic Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: T9-11 (E17-517)
______
Graduate students, postdoctoral fellows, visiting scientists, and guest industrial practitioners to present their own research and highlight important advances from the literature in biochemical and bioprocess engineering. Topics of interest include metabolic engineering, novel microbial pathway design and optimization, synthetic biology, and applications of molecular biology to bioprocess development.
K. J. Prather
No required or recommended textbooks

10.997 Theoretical and Computational Immunology Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Lecture: F12.30-3 (E25-202)
______
Presentations and discussions of current literature and research in theoretical and computational immunology. Topics include T cell biology, cell-cell recognition in immunology, polymers and membranes, and statistical mechanics.
Arup K. Chakraborty
No required or recommended textbooks

10.998 Seminar in Crystallization Science and Technology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: W2-4 (E17-517)
______
Focuses on current topics related to crystallization science and technology in the chemical, pharmaceutical and food industries. Discusses fundamental work on nucleation, polymorphism, impurity crystal interactions and nano-crystal formation, along with industrial applications of crystallization.
A. S. Myerson
No required or recommended textbooks

10.EPE UPOP Engineering Practice Experience
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.EPE,2.EPE,3.EPE,6.EPE,10.EPE,16.EPE,22.EPE)
Prereq: 2.EPW or permission of instructor
Units: 0-0-1 [P/D/F]
TBA.
______
Provides sophomores with guided practice in finding opportunities and excelling in the world of practice. Building on the skills and relationships acquired in the Engineering Practice Workshop, students receive coaching to articulate goals, invoke the UPOP network of mentors and employers, identify and pursue opportunities and negotiate terms of their summer assignment. Students complete a 10-12 week internship, which includes filing three progress reports, conducting one informational interview, and possibly hosting a site visit by MIT staff. Returning to campus as juniors, UPOP students take part in reflective exercises that aid assimilation of learning objectives and reinforce the cognitive link between all aspects of the UPOP experience and disciplinary fields of study. Sequence begins in the spring of sophomore year and ends in the fall of junior year.
Staff
No textbook information available

10.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No textbook information available

10.S94 Special Problems in Chemical Engineering
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Focuses on problem of current interest not covered in regular curriculum; topic varies from year to year.
Staff
No textbook information available

10.S95 Special Problems in Chemical Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Focuses on problem of current interest not covered in regular curriculum; topic varies from year to year.
Staff
No textbook information available

10.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of an SM, PhD, or ScD thesis; to be arranged by the student and appropriate MIT faculty member.
D. Blankschtein
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

10.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Program of research leading to writing an SB thesis; topic arranged between student and MIT faculty member.
B. S. Johnston
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

10.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

10.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Opportunity for participation in a research group, or for special investigation in a particular field. Topic and hours to fit individual requirements.
B. S. Johnston
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|10.00-10.899|10.90-10.999 plus THG, THU, UROP, UPOP|right arrow



Produced: 29-SEP-2016 06:37 AM404 Not Found

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Fall 2016 Course 11: Urban Studies and Planning
Registrar Home | Registrar Search:
 
  MIT Course Picker | MIT Course Planner     
Home | Subject Search | Help | Symbols Help | Pre-Reg Help | Final Exam Schedule
 

Course 11: Urban Studies and Planning
Fall 2016


Introductory Subjects

11.001[J] Introduction to Urban Design and Development
______

Undergrad (Fall) HASS Humanities
(Same subject as4.250[J])
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4250
Lecture: MW11-12.30 (2-105) +final
______
Examines the evolving structure of cities and the way that cities, suburbs, and metropolitan areas can be designed and developed. Surveys the ideas of a wide range of people who have addressed urban problems. Stresses the connection between values and design. Demonstrates how physical, social, political and economic forces interact to shape and reshape cities over time.
L. Vale
No required or recommended textbooks

11.002[J] Making Public Policy
______

Undergrad (Fall) HASS Social Sciences Communication Intensive HASS
(Same subject as17.30[J])
Prereq: None
Units: 4-0-8
URL: http://web.mit.edu/17.30j/www/
Lecture: MW9.30-11 (4-237) Recitation: R3 (66-148) or R4 (66-148) or F11 (1-134) or F12 (1-134)
______
Examines how the struggle among competing advocates shapes the outputs of government. Considers how conditions become problems for government to solve, why some political arguments are more persuasive than others, why some policy tools are preferred over others, and whether policies achieve their goals. Investigates the interactions among elected officials, think tanks, interest groups, the media, and the public in controversies over global warming, urban sprawl, Social Security, health care, education, and other issues.
Staff
No textbook information available

11.003[J] Methods of Policy Analysis
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Social Sciences
(Same subject as17.303[J])
Prereq: 11.002J;Coreq: 14.01
Units: 3-0-9
______
Provides students with an introduction to public policy analysis. Examines various approaches to policy analysis by considering the concepts, tools, and methods used in economics, political science, and other disciplines. Students apply and critique these approaches through case studies of current public policy problems.
Staff

11.005 Introduction to International Development
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-0-9
______
Introduces the political economy of international economic development planning, using an applied, quantitative approach. Considers why some countries are able to develop faster than others. Presents major theories and models of development and underdevelopment, providing tools to understand the mechanisms and processes behind economic growth and broader notions of progress. Offers an alternative view of development, focusing on the persistence of dichotomies in current theory and practice. Using specific cases, explores how different combinations of actors and institutions at various scales may promote or inhibit economic development. Students re-examine conventional knowledge and engage critically with the assumptions behind current thinking and policy.
Y. Hong, C. Cardoso

11.006 Poverty and Economic Security
______

Not offered academic year 2017-2018Undergrad (Fall) HASS Social Sciences
(Subject meets with11.206)
Prereq: None
Units: 3-0-9
Lecture: TR9.30-11 (9-255)
______
Explores the evolution of poverty and economic security in the US within a global context. Examines the impacts of recent economic restructuring and globalization. Reviews current debates about the fate of the middle class, sources of increasing inequality, and approaches to advancing economic opportunity and security. Students taking graduate version complete additional assignments.
A. Glasmeier
No textbook information available

11.011 The Art and Science of Negotiation
______

Undergrad (Fall, Spring) HASS Social Sciences
Prereq: None
Units: 3-0-9
URL: http://dusp.mit.edu/subject/spring-2016-11011
Lecture: MW3-4.30 (9-255)
______
Introduction to negotiation theory and practice. Applications in government, business, and nonprofit settings are examined. Combines a "hands-on" personal skill-building orientation with a look at pertinent theory. Strategy, communications, ethics, and institutional influences are examined as they shape the ability of actors to analyze problems, negotiate agreements, and resolve disputes in social, organizational, and political circumstances characterized by interdependent interests.
B. Verdini
No textbook information available

11.013[J] American Urban History I
______

Undergrad (Fall) HASS Humanities Communication Intensive HASS
(Same subject as21H.217[J])
Prereq: None
Units: 2-0-7
Lecture: T2-4 (9-217)
______
Seminar on the history of institutions and institutional change in American cities from roughly 1850 to the present. Among the institutions to be looked at are political machines, police departments, courts, schools, prisons, public authorities, and universities. Focuses on readings and discussions.
R. M. Fogelson
No textbook information available

11.014[J] American Urban History II
______

Undergrad (Fall) HASS Humanities Communication Intensive HASS
(Same subject as21H.218[J])
Prereq: None
Units: 2-0-7
Lecture: R2-4 (9-450A)
______
Seminar on the history of selected features of the physical environment of urban America. Among the features considered are parks, cemeteries, tenements, suburbs, zoos, skyscrapers, department stores, supermarkets, and amusement parks.
R. M. Fogelson
Textbooks (Fall 2016)

11.015[J] Riots, Strikes, and Conspiracies in American History
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Humanities Communication Intensive HASS
(Same subject as21H.226[J])
Prereq: None
Units: 3-0-9
______
Focuses on a series of short, complicated, traumatic events that shed light on American politics, culture, and society. Events studied may include the rendition of Anthony Burns in 1854, the most famous fugitive slave controversy in US history; the Homestead strike/lockout of 1892; the quiz show scandal of the 1950s; and the student uprisings at Columbia University in 1968. Emphasis on finding ways to make sense of these events and on using them to understand larger processes of change in American history.
R. M. Fogelson

11.016[J] The Once and Future City
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Humanities Communication Intensive HASS
(Same subject as4.211[J])
Prereq: None
Units: 3-0-9
______
Examines the evolving structure of cities, the dynamic processes that shape them, and the significance of a city's history for its future development. Develops the ability to read urban form as an interplay of natural processes and human purposes over time. Field assignments in Boston provide the opportunity to use, develop, and refine these concepts. Enrollment limited.
A. Spirn

11.021[J] Environmental Law, Policy, and Economics: Pollution Prevention and Control
______

Undergrad (Fall) HASS Social Sciences
(Same subject as1.801[J],17.393[J])
(Subject meets with1.811[J],11.630[J],IDS.430[J])
Prereq: None
Units: 3-0-9
Credit cannot also be received for15.663
Lecture: TR3.30-5 (E51-057) +final
______
Introduction to important issues in contemporary environmental law, policy, and economics. Discusses the roles and interactions of Congress, federal agencies, state governments, and the courts in dealing with environmental problems. Topics include common law, administrative law, environmental impact assessments required by the National Environmental Policy Act, and legislation and court decisions dealing with air pollution, water pollution, the control of hazardous waste, pollution and accident prevention, the production and use of toxic chemicals, community right-to-know, and environmental justice. Explores the role of science and economics in legal decisions, and economic incentives as an alternative or supplement to regulation. Analyzes pollution as an economic problem and a failure of markets. Introduction to basic legal skills: how to read and understand cases, regulation, and statutes; how to discover the current state of the law in a specific area; and how to take action toward resolution of environmental problems. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C. Caldart
Textbooks (Fall 2016)

11.022[J] Regulation of Chemicals, Radiation, and Biotechnology
______

Undergrad (Spring)
Not offered regularly; consult department
(Same subject as1.802[J])
(Subject meets with1.812[J],10.805[J],11.631[J],IDS.431[J],IDS.436[J])
Prereq: 1.801 or permission of instructor
Units: 3-0-9
______
Focuses on policy design and evaluation in the regulation of hazardous substances and processes. Includes risk assessment, industrial chemicals, pesticides, food contaminants, pharmaceuticals, radiation and radioactive wastes, product safety, workplace hazards, indoor air pollution, biotechnology, victims' compensation, and administrative law. Health and economic consequences of regulation, as well as its potential to spur technological change, are discussed for each regulatory regime. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C. Caldart

11.025[J] D-Lab: Development
______

Undergrad (Fall) HASS Social Sciences
(Same subject asEC.701[J])
(Subject meets with11.472[J],EC.781[J])
Prereq: None
Units: 3-2-7
Lecture: MWF3.30-5 (N51-310)
______
Issues in international development, appropriate technology and project implementation addressed through lectures, case studies, guest speakers and laboratory exercises. Students form project teams to partner with community organizations in developing countries, and formulate plans for an optional IAP site visit. (Previous field sites include Ghana, Brazil, Honduras and India.) Recitation sections focus on specific project implementation, and include cultural, social, political, environmental and economic overviews of the target countries as well as an introduction to the local languages. Enrollment limited by lottery; must attend first class session.
S. L. Hsu, A. B. Smith, B. Sanyal
No textbook information available

11.026[J] Downtown
______

Undergrad (Spring) HASS Humanities
(Same subject as21H.321[J])
(Subject meets with11.339)
Prereq: None
Units: 2-0-7
______
Seminar on downtown in US cities from the late 19th century to the late 20th. Emphasis on downtown as an idea, place, and cluster of interests, on the changing character of downtown, and on recent efforts to rebuild it. Considers subways, skyscrapers, highways, urban renewal, and retail centers. Focus on readings, discussions, and individual research projects. Students taking graduate version complete additional assignments.
R. M. Fogelson

11.027 City to City: Comparing, Researching and Writing about Cities
______

Undergrad (Spring) HASS Social Sciences
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces client-oriented research and the use of urban planning tools. Students work directly with government and community agencies to find solutions to real world problems; interview planners and other field experts, and write and present findings to client and community audiences. Opportunity to travel for research. Limited to 14; preference to Course 11 majors.
C. Abbanat

Specialized Subjects

11.123 Big Plans and Mega-Urban Landscapes
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-0-6
______
Explores the physical, ecological, technological, political, economic and cultural implications of big plans and mega-urban landscapes in a global context. Uses local and international case studies to understand the process of making major changes to urban landscape and city fabric, and to regional landscape systems. Includes lectures by leading practitioners. Assignments consider planning and design strategies across multiple scales and time frames.
L. Shi

11.124 Introduction to Education: Looking Forward and Looking Back on Education
______

Undergrad (Fall) HASS Social Sciences Communication Intensive HASS
Prereq: None
Units: 3-6-3
URL: https://moodle.mit.edu/course/view.php?id=7
Lecture: TR2.30-4 (56-154)
______
One of two introductory subjects on teaching and learning science and mathematics in a variety of K-12 settings. Topics include education and media, education reform, the history of education, simulations, games, and the digital divide. Students gain practical experience through weekly visits to schools, classroom discussions, selected readings, and activities to develop a critical and broad understanding of past and current forces that shape the goals and processes of education, and explores the challenges and opportunities of teaching. Students work collaboratively and individually on papers, projects, and in-class presentations.
E. Klopfer
No textbook information available

11.125 Introduction to Education: Understanding and Evaluating Education
______

Undergrad (Spring) HASS Social Sciences Communication Intensive HASS
Prereq: None
Units: 3-6-3
______
One of two introductory subjects on teaching and learning science and mathematics in a variety of K-12 settings. Topics include student misconceptions, formative assessment, standards and standardized testing, multiple intelligences, and educational technology. Students gain practical experience through weekly visits to schools, classroom discussions, selected readings, and activities to develop a critical and broad understanding of past and current forces that shape the goals and processes of education, and explores the challenges and opportunities of teaching. Students work collaboratively and individually on papers, projects, and in-class presentations.
E. Klopfer

11.127[J] Design and Development of Games for Learning
______

Undergrad (Spring) HASS Humanities
(Same subject asCMS.590[J])
(Subject meets with11.252[J],CMS.863[J])
Prereq: None
Units: 3-6-3
______
Immerses students in the process of building and testing their own digital and board games in order to better understand how we learn from games. Explores the design and use of games in the classroom in addition to research and development issues associated with computer-based (desktop and handheld) and non-computer-based media. In developing their own games, students examine what and how people learn from them (including field testing of products), as well as how games can be implemented in educational settings. All levels of computer experience welcome. Students taking graduate version complete additional assignments.
E. Klopfer

11.129 Educational Theory and Practice I
______

Undergrad (Fall) HASS Social Sciences
Prereq: None.Coreq: 11.124
Units: 3-0-9
URL: https://sites.google.com/site/miteducationaltheorypractice/
Lecture: TR4-5.30 (1-134)
______
Concentrates on core set of skills and knowledge necessary for teaching in secondary schools. Topics include classroom management, student behavior and motivation, curriculum design, educational reform, and the teaching profession. Classroom observation is a key component. Assignments include readings from educational literature, written reflections on classroom observations, practice teaching and constructing curriculum. The first of the three-course sequence necessary to complete the Teacher Education Program. Limited to 15; preference to juniors and seniors.
G. Schwanbeck
No textbook information available

11.130 Educational Theory and Practice II
______

Undergrad (IAP)
Prereq: 11.129
Units: 3-0-9
______
Concentrates on the theory and psychology associated with student learning. Topics include educational theory, educational psychology, and theories of learning. Students assume responsibility for full-time teaching of two or more classes at their designated school. Class sessions focus on debriefing and problem-solving. Second of a three-course sequence necessary to complete the Teacher Education Program.
G. Schwanbeck

11.131 Educational Theory and Practice III
______

Undergrad (Spring) HASS Social Sciences
Prereq: 11.130
Units: 3-0-9
______
Students continue their IAP student teaching through mid March. Topics include educational psychology, theories of learning, and using technology and evaluating its effectiveness to enhance student learning. Assignments include readings from educational literature, written reflections on student teaching, presentations on class topics and creating a project that supports student learning at the school where the MIT student is teaching. This is the third of the three-course sequence necessary to complete the Teacher Education Program.
G. Schwanbeck

11.137 Financing Economic Development
______

Undergrad (Fall)
(Subject meets with11.437)
Prereq: None
Units: 4-0-8
Lecture: MW11-12.30 (8-205) Recitation: F1.30 (10-401)
______
Focuses on financing tools and program models to support local economic development. Provides an overview of private capital markets and financing sources to understand capital market imperfections that constrain economic development, business accounting, financial statement analysis, federal economic development programs, and public finance tools. Covers policies and program models, including revolving loan funds, guarantee programs, venture capital funds, bank holding companies, community development loan funds and credit unions, micro enterprise funds, and the Community Reinvestment Act. Students taking graduate version complete additional assignments. Limited to 25.
K. Seidman
Textbooks (Fall 2016)

11.139 The City in Film
______

Undergrad (Spring) HASS Humanities Communication Intensive HASS
(Subject meets with11.239)
Prereq: None
Units: 2-2-5
______
Surveys important developments in urbanism from 1900 to the present, using film as a lens to explore and interpret aspects of the urban experience in the US and abroad. Topics include industrialization, demographics, diversity, the environment, and the relationship between the community and the individual. Films vary from year to year but always include a balance of classics from the history of film, an occasional experimental/avant-garde film, and a number of more recent, mainstream movies. Students taking undergraduate version complete writing assignments that focus on observation, analysis, and the essay, and give an oral presentation. Limited to 18.
E. Glenn

11.140 Urbanization and Development
______

Undergrad (Spring) HASS Social Sciences
(Subject meets with11.480)
Prereq: None
Units: 3-0-9
______
Examines developmental dynamics of rapidly urbanizing locales, with a special focus on the developing world. Case studies from India, China, Mexico, Brazil, and South Africa form the basis for discussion of social, spatial, political and economic changes in cities spurred by the decline of industry, the rise of services, and the proliferation of urban mega projects. Emphasizes the challenges of growing urban inequality, environmental risk, citizen displacement, insufficient housing, and the lack of effective institutions for metropolitan governance. Students taking graduate version complete additional assignments.
Staff

11.142 Geography of the Global Economy
______

Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-0-9
______
Analyzes implications of economic globalization for communities, regions, international businesses and economic development organizations. Uses spatial analysis techniques to model the role of energy resources in shaping international political economy. Investigates key drivers of human, physical, and social capital flows and their roles in modern human settlement systems. Surveys contemporary models of industrialization and places them in geographic context. Connects forces of change with their implications for the distribution of wealth and human well-being.
A. Glasmeier

11.144 Project Appraisal in Developing Countries
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with11.484)
Prereq: Permission of instructor
Units: 3-0-9
______
Covers techniques of financial analysis of investment expenditures, as well as the economic and distributive appraisal of development projects. Critical analysis of these tools in the political economy of international development is discussed. Topics include appraisal's role in the project cycle, planning under conditions of uncertainty, constraints in data quality and the limits of rational analysis, and the coordination of an interdisciplinary appraisal team. Students taking graduate version complete additional assignments. Enrollment limited; preference to majors.
Y. Hong

11.145 International Housing Economics and Finance
______

Undergrad (Spring)
Prereq: 14.01
Units: 3-0-6
Credit cannot also be received for11.355
______
Presents a theory of comparative differences in international housing outcomes. Introduces institutional differences in the ways housing expenditures are financed, and the economic determinants of housing outcomes, such as construction costs, land values, housing quality, and ownership rates. Analyzes the flow of funds to and from the different national housing finance sectors. Develops an understanding of the greater financial and macroeconomic implications of the mortgage credit sector, and how policies affect the ways in which housing asset fluctuations impact national economies. Considers the perspective of investors in international real estate markets and the risks and rewards involved. Draws on lessons from an international comparative approach, and applies them to economic and finance policies at the local, state/provincial, and federal levels within a country of choice. Meets with 11.355 when offered concurrently. Students taking graduate version complete additional assignments.
A. Saiz

11.146 Urbanizing China
______

Undergrad (Fall)
Not offered regularly; consult department
(Subject meets with11.476)
Prereq: None
Units: 2-0-7
URL: http://dusp.mit.edu/subject/fall-2014-11s945
______
Discusses China's daunting urban challenges: congestion and smog, housing affordability, land reform and urban financing, migrants and locals, and social and spatial inequality. Provides examples of laudable achievements and diverse and innovative responses across more than six hundred cities. Presents China's urbanization as the joint result of natural socioeconomic processes and conscious actions by governments, markets, and the public. Presents multidisciplinary approaches and alternative narratives. Examines the intricate interaction between state and market in China's context, yielding a variety of state-market 'cocktails' devised and experimented in different cities in response to local problems, each involving a multilayered projection onto urban space. Students taking graduate version complete additional assignments.
J. Zhao

11.147 Budgeting and Finance for the Public Sector
______

Undergrad (Spring) HASS Social Sciences
(Subject meets with11.487)
Prereq: Permission of instructor
Units: 3-0-9
______
Examines globally relevant challenges of adequately and effectively attending to public sector responsibilities for basic services with limited resources. Particular attention to the contexts of fiscal crises and rapid population growth, as well as shrinkage, through an introduction to methods and processes of budgeting, accounting, and financial mobilization. Case studies and practice exercises explore revenue strategies, demonstrate fiscal analytical competencies, and familiarize students with pioneering examples of promising budget and accounting processes and innovative funding mobilization via taxation, capital markets, and other mechanisms (e.g., land-value capture). Students taking graduate version explore the subject in greater depth.
G. Carolini

11.148 Environmental Justice: Law and Policy
(New)
______

Not offered academic year 2017-2018Undergrad (Fall)
(Subject meets with11.368)
Prereq: None
Units: 3-0-9
Lecture: M2-5 (9-217)
______
Introduces frameworks for analyzing and addressing inequalities in the distribution of environmental benefits and burdens. Explores the foundations and principles of the environmental justice movement from the perspectives of social science, public policy, and law. Applies environmental justice principles to contemporary issues in urban policy and planning. Students taking graduate version complete additional assignments.
J. Steil
No textbook information available

11.150[J] Metropolis: A Comparative History of New York City
______

Undergrad (Fall) HASS Humanities
(Same subject as21H.220[J])
Prereq: None
Units: 3-0-9
Lecture: W EVE (7-10 PM) (2-135)
______
Examines the evolution of New York City from 1607 to the present. Readings focus on the city's social and physical histories. Discussions compare New York's development to patterns in other cities.
C. Wilder
Textbooks (Fall 2016)

11.151[J] Youth Political Participation
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Humanities
(Same subject asSTS.080[J])
Prereq: None
Units: 3-0-9
______
Surveys youth political participation in the US since the early 1800s. Investigates trends in youth political activism during specific historical periods, as well as what difference youth media production and technology use (e.g., radio, music, automobiles, ready-made clothing) made in determining the course of events. Explores what is truly new about "new media" and reviews lessons from history for present-day activists based on patterns of past failure and success. Some mandatory field trips may occur during class time. Limited to 40.
J. S. Light

11.152[J] The Ghetto: From Venice to Harlem
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject as21H.385[J])
Prereq: None
Units: 2-0-10
______
Provides an in-depth look at a modern institution of oppression: the ghetto. Uses literature to examine ghettoization over time and across a wide geographical area, from Jews in Medieval Europe to African-Americans and Latinos in the 20th-century United States. Also explores segregation and poverty in the urban "Third World."
C. Wilder

11.153[J] Shanghai and China's Modernization
______

Undergrad (Spring) HASS Humanities
(Same subject as21H.351[J])
Prereq: None
Units: 2-0-10
______
Considers the history and function of Shanghai, from 1840 to the present, and its rise from provincial backwater to international metropolis. Examines its role as a primary point of economic, political, and social contact between China and the world, and the strong grip Shanghai holds on both the Chinese and foreign imagination. Students discuss the major events and figures of Shanghai, critique the classic historiography, and complete an independent project on Shanghai history.
C. Leighton

11.156 Healthy Cities: Assessing Health Impacts of Policies and Plans
(New)
______

Undergrad (Spring)
(Subject meets with11.356)
Prereq: None
Units: 3-0-9
______
Examines the built, psychosocial, economic, and natural environment factors that affect health behaviors and outcomes. Introduces tools designed to integrate public health considerations into policymaking and planning. Provides extensive practical training in the application of health impact assessment (HIA) methodology, which brings a health lens to policy, budgeting, and planning debates. Emphasizes health equity and healthy cities. Students taking graduate version complete additional assignments. Limited to 30.
M. Arcaya

11.161[J] Energy Decisions, Markets, and Policies
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject as14.43[J],15.031[J],17.397[J],21A.415[J])
Prereq: 14.01, 15.0111, or permission of instructor
Units: 4-0-8
______
Structured around choices and constraints regarding sources and uses of energy by households, firms, and governments, introduces managerial, economic, political, social and cultural frameworks for describing and explaining behavior at various levels of aggregation. Includes examples of cost-benefit, organizational and institutional analyses of energy generation, distribution, and consumption. Topics include the role of markets and prices; financial analysis of energy-related investments; institutional path dependence; economic and political determinants of government regulation and the impact of regulation on decisions; and other forms of government action and social norms regarding desired behavior and opportunities for businesses and consumers, including feedback into the political/regulatory system. Examples drawn from a wide range of countries and settings.
C. Warshaw

11.162 Politics of Energy and the Environment
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Social Sciences
Prereq: None
Units: 3-0-9
______
Focuses on the politics of making local, state, national and international decisions on energy and the environment. Topics include implementing energy efficiency measures, siting nuclear and alternative energy plants, promoting oil and gas development offshore and in wilderness, adapting to climate change, handling toxic waste, protecting endangered species, and conserving water. Case studies include Cape Wind, disputes over oil and gas exploration in the Arctic, the response to Hurricane Katrina, and efforts to craft and comply with the greenhouse gas emissions limits.
Staff

11.163[J] Law and Society
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject as17.249[J],21A.455[J])
(Subject meets with21A.459)
Prereq: None
Units: 3-0-9
______
Studies legal reasoning, types of law and legal systems, and relationship of law to social class and social change. Emphasizes the profession and practice of law, including legal education, stratification within the bar, and the politics of legal services. Investigates emerging issues in the relationship between institutions of law and science.
S. Silbey

11.164[J] Human Rights at Home and Abroad
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject as17.391[J])
(Subject meets with11.497)
Prereq: Permission of instructor
Units: 3-0-9
______
Provides a rigorous and critical introduction to the history, foundation, structure, and operation of the human rights movement. Focuses on key ideas, actors, methods and sources, and critically evaluates the field. Addresses current debates in human rights, including the relationship with security, democracy, development and globalization, urbanization, equality (in housing and other economic and social rights; women's rights; ethnic, religious and racial discrimination; and policing/conflict), post-conflict rebuilding and transitional justice, and technology-related issues. Prior coursework, work experience, or community service that demonstrates familiarity with global affairs or engagement with ethics and social justice issues, preferred. Students taking graduate version expected to write a research paper.
B. Rajagopal

11.165 Urban Energy Systems and Policy
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Subject meets with1.286[J],11.477[J])
Prereq: 14.01 or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Examines efforts in developing and advanced nations and regions. Examines key issues in the current and future development of urban energy systems, such as technology, use, behavior, regulation, climate change, and lack of access or energy poverty. Case studies on a diverse sampling of cities explore how prospective technologies and policies can be implemented. Includes intensive group research projects, discussion, and debate. Students taking the graduate version complete additional assignments.
D. Hsu

11.166 Law, Social Movements, and Public Policy: Comparative and International Experience
______

Undergrad (Spring) HASS Social Sciences
(Subject meets with11.496)
Prereq: Permission of instructor
Units: 3-0-9
______
Studies the interaction between law, courts, and social movements in shaping domestic and global public policy. Examines how groups mobilize to use law to affect change and why they succeed and fail. Case studies explore the interplay between law, social movements, and public policy in current issues, such as gender, race, labor, trade, climate change/environment, and LGBTQ rights. Introduces theories of public policy, social movements, law and society, and transnational studies. Students taking graduate version complete additional assignments. Limited to 15.
B. Rajagopal

11.169 Global Climate Policy and Sustainability
(New)
______

Undergrad (Spring)
Prereq: None
Units: 3-0-9
______
Examines climate politics both nationally and globally. Addresses economic growth, environmental preservation, and social equity through the lens of sustainability. Uses various country and regional cases to analyze how sociopolitical, economic and environmental values shape climate policy. Students develop recommendations for making climate policy more effective and sustainable. Limited to 25.
J. Knox-Hayes

11.183 Property and Land Use Law for Planners
______

Not offered academic year 2017-2018Undergrad (Fall)
(Subject meets with11.493)
Prereq: None
Units: 3-0-9
Lecture: W2-5 (9-450B)
______
Examines legal and institutional arrangements for the establishment, transfer, and control over property under American and selected comparative systems, including India and South Africa. Focuses on key issues of property and land use law regarding planning and economic development. Emphasizes just and efficient resource use; institutional, entitlement and social relational approaches to property; distributional and other social aspects; and the relationship between property, culture, and democracy.
B. Rajagopal
No textbook information available

Laboratories

11.188 Urban Planning and Social Science Laboratory
______

Undergrad (Spring) Institute Lab
Prereq: None
Units: 3-3-6
Credit cannot also be received for11.205
______
An introduction to the research and empirical analysis of urban planning issues using geographic information systems. Extensive hands-on exercises provide experience with various techniques in spatial analysis and querying databases. Includes a small project on an urban planning problem involving the selection of appropriate methods, the use of primary and secondary data, computer-based modeling, and spatial analysis. Requires some computing experience.
J. Ferreira

Tutorials, Fieldwork, and Internships

11.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually

11.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Undergraduate research opportunities in Urban Studies and Planning. For further information, consult the Departmental Coordinators.
E. Klopfer
Textbooks arranged individually

11.THT[J] Thesis Research Design Seminar
______

Undergrad (Fall) Can be repeated for credit
(Same subject as4.THT[J])
Prereq: None
Units: 3-0-9
Lecture: F12-3 (9-217)
______
Designed for students writing a thesis in Urban Studies and Planning or Architecture. Develop research topics, review relevant research and scholarship, frame research questions and arguments, choose an appropriate methodology for analysis, and draft introductory and methodology sections.
C. Abbanat
No required or recommended textbooks

11.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 11.THT
Units arranged
TBA.
______
Program of research leading to the writing of an SB thesis. To be arranged by the student under approved supervision.
Staff
Textbooks arranged individually

11.189-11.190 Urban Fieldwork
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
11.189: TBA.
11.190: TBA.
______
Practical application of city and regional planning techniques to towns, cities, and regions, including problems of replanning, redevelopment, and renewal of existing communities. Includes internships, under staff supervision, in municipal and state agencies and departments.
Staff
11.189: No required or recommended textbooks
11.190: No required or recommended textbooks

11.191-11.192 Independent Study
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
11.191: TBA.
11.192: TBA.
______
For undergraduates wishing to pursue further study in specialized areas of urban studies or city and regional planning not covered in regular subjects.
Staff
11.191: No required or recommended textbooks
11.192: No required or recommended textbooks

11.193-11.194 Supervised Readings
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
11.193: TBA.
11.194: TBA.
______
Reading and discussion of topics in urban studies and planning.
Staff
11.193: No required or recommended textbooks
11.194: No required or recommended textbooks

11.S195 Special Subject: Urban Studies and Planning
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
11.S195: URL: https://dusp.mit.edu/subject/fall-2016-11s195
11.S195: Lecture: TR1-2.30 (56-154)
Subject Cancelled 11.S196 Cancelled
Subject Cancelled 11.S197 Cancelled
Subject Cancelled 11.S198 Cancelled
Subject Cancelled 11.S199 Cancelled
______
11.S195: No textbook information available

11.S196-11.S199 Special Subject: Urban Studies and Planning
______

Undergrad (Spring) Can be repeated for credit
Prereq: None
Units arranged
11.S195: URL: https://dusp.mit.edu/subject/fall-2016-11s195
11.S195: Lecture: TR1-2.30 (56-154)
Subject Cancelled 11.S196 Cancelled
Subject Cancelled 11.S197 Cancelled
Subject Cancelled 11.S198 Cancelled
Subject Cancelled 11.S199 Cancelled
______
For undergraduates wishing to pursue further study or fieldwork in specialized areas of urban studies or city and regional planning not covered in regular subjects of instruction. 11.S198 is graded P/D/F.
Staff
11.S195: No textbook information available


left arrow|Undergraduate: 11.00-11.199
plus UROP, ThU, ThT
|Graduate: 11.20-11.299|Graduate: 11.30-11.999 plus ThG|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 11: Urban Studies and Planning
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Course 11: Urban Studies and Planning
Fall 2016


Master's Core Subjects

11.201 Gateway: Planning Action
______

Graduate (Fall)
Prereq: None
Units: 4-1-7
Lecture: MW11-12.30 (9-354) Recitation: F12-1.30 (9-450A) or F1.30-3 (9-450A, 9-450B) or F3-4.30 (9-450A, 9-451)
______
Introduces the profession of urban and regional planning. Emphasizes the key sensibilities necessary for effective planning practice as well as professional writing and oral communication skills.
J. Buckley
No textbook information available

11.202 Planning Economics
______

Graduate (Fall); partial term
Prereq: 11.203
Units: 2-0-2
Begins Oct 24. Lecture: TR11-12.30 (9-354) Recitation: R EVE (5-6.30 PM) (9-450A) or R3.30-5 (9-450B) or F10.30-12 (9-451)
______
Introduces applications of microeconomic theory to planning problems including urban form and structure, government's role in urban settings and problems of housing finance.
A. Saiz
No textbook information available

11.203 Microeconomics
______

Graduate (Fall); partial term
Prereq: None
Units: 3-0-5
Ends Oct 21. Lecture: TR11-12.30 (9-354) Recitation: R EVE (5-6.30 PM) (9-450A) or R3.30-5 (9-450B) or F10.30-12 (9-451)
______
Introduces basic economic analysis for planning students including the functioning of markets, the allocation of scarce resources among competing uses, profit maximizing behavior in different market structures. Course illustrates theory with contemporary economic issues.
A. Saiz
Textbooks (Fall 2016)

11.205 Introduction to Spatial Analysis
______

Graduate (Fall, Spring); partial term
Prereq: None
Units: 2-2-2
Credit cannot also be received for11.188
Ends Oct 28. Lecture: MW2.30-4 (9-354) Lab: M EVE (5-7 PM) (W31-301) or T EVE (5-7 PM) (W31-301) or W EVE (5-7 PM) (W31-301) or R EVE (5-7 PM) (W31-301)
______
Practical introduction to spatial analysis and geographic information systems (GIS). Examines how geography is represented digitally and how nonrandom distributions of phenomena as diverse as poverty and scenic resources can be better understood by examining their spatial characteristics. Limited enrollment; preference to first-year MCP students.
Fall:S. Williams
Spring:J. Ferreira
No textbook information available

11.206 Poverty and Economic Security
(New)
______

Not offered academic year 2017-2018Graduate (Fall)
(Subject meets with11.006)
Prereq: None
Units: 3-0-9
Lecture: TR9.30-11 (9-255)
______
Explores the evolution of poverty and economic security in the US within a global context. Examines the impacts of recent economic restructuring and globalization. Reviews current debates about the fate of the middle class, sources of increasing inequality, and approaches to advancing economic opportunity and security. Students taking graduate version complete additional assignments.
A. Glasmeier
No textbook information available

11.220 Quantitative Reasoning and Statistical Methods for Planning I
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 4-2-6
______
Develops logical, empirically based arguments using statistical techniques and analytic methods. Covers elementary statistics, probability, and other types of quantitative reasoning useful for description, estimation, comparison, and explanation. Emphasizes the use and limitations of analytical techniques in planning practice. Restricted to MCP students.
J. Zhao

Department-wide Subjects

11.225 Argumentation and Communication
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units: 2-0-4
______
A writing practicum associated with 11.201 that focuses on helping students write and present their ideas in cogent, persuasive arguments and other analytical frameworks. Reading and writing assignments and other exercises stress the connections between clear thinking, critical reading, and effective writing.
C. Abbanat

11.229 Advanced Writing Seminar
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: None
Units: 2-0-7
______
Focuses on writing and speaking skills. Students bring their writing from other classes to the workshop to practice reviewing and rewriting skills and make several oral presentations. Different types of writing including proposals, memos, thesis, press releases, and writing sound bites for the media.
C. Abbanat

11.233 Research Design for Policy Analysis and Planning
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: T9.30-12.30 (9-217)
______
Develops skills in research design for policy analysis and planning. Emphasizes the logic of the research process and its constituent elements. Topics include philosophy of science, question formulation, hypothesis generation and theory construction, data collection techniques (e.g. experimental, survey, interview), ethical issues in research, and research proposal preparation. Limited to doctoral students in Course 11.
G. Carolini
No textbook information available

11.234 Making Sense: Qualitative Methods for Designers and Planners
______

Graduate (Spring)
Prereq: None
Units: 3-3-6
______
Surveys uses of qualitative methods in urban design and planning research and practice. Topics include observing environments, physical traces, and environmental behavior; asking questions; focused interviews; standardized questionnaires; use of written archival materials; use of visual materials, including photographs, new media, and maps; case studies; and comparative methods. Emphasizes use of each of these skills to collect and make sense of qualitative data in community and institutional settings.
Staff

11.236 Theory of Participatory Action Research (PAR)
______

Graduate (Fall); partial term
Prereq: None
Units: 2-0-4
URL: http://dusp.mit.edu/subject/fall-2014-11s944
Ends Oct 21. Lecture: TR EVE (5-6.30 PM) (9-451)
______
Introduces the theory of participatory action research (PAR) and competing ideas about the uses of social research to promote social change. Focuses on the epistemological foundation for and knowledge generation in action research, as well as on approaches to co-producing research that requires engagement of the subjects, communities, or organizations that are being studied in the design, implementation and interpretation of applied social research. Explores the ethical obligations of outsiders along with rights and responsibilities of insiders in the research findings. Emphasizes recent scholarship, including arguments for and against phronetic social science.
L. Susskind, D. Cunningham
Textbooks (Fall 2016)

11.237 Practice of Participatory Action Research (PAR)
______

Graduate (Spring); partial term
Prereq: 11.236 or permission of instructor
Units: 3-0-3
______
Introduces the techniques of participatory action research (PAR) and the practice of case study research. Presents competing ideas about context-independent vs. context-dependent knowledge, arguments for and against generating theory on the basis of a single case, and problems of verification in PAR (i.e., disconfirming the researchers preconceptions). Focuses on actual cases in which PAR-like methods have been used with greater or lesser success. Integrates interactions with representatives of communities, organizations, and individuals who have been the focus of PAR. Analyzes techniques for co-designing and co-conducting all aspects of applied social research.
L. Susskind, D. Cunningham

11.238[J] Ethics of Intervention
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as21A.409[J])
Prereq: Permission of instructor
Units: 3-0-9
______
An historical and cross-cultural study of the logics and practices of intervention: the ways that individuals, institutions, and governments identify conditions of need or states of emergency within and across borders that require a response. Examines when a response is viewed as obligatory, when is it deemed unnecessary, and by whom; when the intercession is considered fulfilled; and the rationales or assumptions that are employed in assessing interventions. Theories of the state, globalization, and humanitarianism; power, policy, and institutions; gender, race, and ethnicity; and law, ethics, and morality are examined.
E. C. James

11.239 The City in Film
______

Graduate (Spring)
(Subject meets with11.139)
Prereq: Permission of instructor
Units: 2-2-5
______
Surveys important developments in urbanism from 1900 to the present, using film as a lens to explore and interpret aspects of the urban experience in the US and abroad. Topics include industrialization, demographics, diversity, the environment, and the relationship between the community and the individual. Films vary from year to year but always include a balance of classics from the history of film, an occasional experimental/avant-garde film, and a number of more recent, mainstream movies. Students taking undergraduate version complete writing assignments that focus on observation, analysis, and the essay, and give an oral presentation.
E. Glenn

11.250 Transportation Research Design
(New)
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of Instructor
Units: 2-0-1 [P/D/F]
Lecture: F12-1.30 (9-450B)
______
Seminar dissects ten transportation studies from head to toe to illustrate how research ideas are initiated, framed, analyzed, evidenced, written, presented, criticized, revised, extended, and published, quoted and applied. Students design and execute their own transportation research. Limited to 20.
J. Zhao
No required or recommended textbooks

11.252[J] Design and Development of Games for Learning
______

Graduate (Spring)
(Same subject asCMS.863[J])
(Subject meets with11.127[J],CMS.590[J])
Prereq: None
Units: 3-6-3
______
Immerses students in the process of building and testing their own digital and board games in order to better understand how we learn from games. Explores the design and use of games in the classroom in addition to research and development issues associated with computer-based (desktop and handheld) and non-computer-based media. In developing their own games, students examine what and how people learn from them (including field testing of products), as well as how games can be implemented in educational settings. All levels of computer experience welcome. Students taking graduate version complete additional assignments.
E. Klopfer

11.255 Negotiation and Dispute Resolution in the Public Sector
______

Graduate (Spring)
Prereq: None
Units: 4-0-8
______
Investigates social conflict and distributional disputes in the public sector. While theoretical aspects of conflict and consensus building are considered, focus is on the practice of negotiation and dispute resolution. Comparisons between unassisted and assisted negotiation are reviewed along with the techniques of facilitation and mediation.
L. Susskind


left arrow|Undergraduate: 11.00-11.199
plus UROP, ThU, ThT
|Graduate: 11.20-11.299|Graduate: 11.30-11.999 plus ThG|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 11: Urban Studies and Planning
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Course 11: Urban Studies and Planning
Fall 2016


Program Group Subjects

11.301[J] Introduction to Urban Design and Development
______

Graduate (Fall)
(Same subject as4.252[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR9.30-11 (9-354)
______
Examines both the structure of cities and ways they can be changed. Includes historical forces that have produced cities, models of urban analysis, contemporary theories of urban design, implementation strategies. Core lectures supplemented by discussion sessions focusing on student work and field trips. Guest speakers present cases involving current projects illustrating the scope and methods of urban design practice.
D. Frenchman
No required or recommended textbooks

11.302[J] Urban Design Politics
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as4.253[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Examines ways urban design contributes to distribution of political power and resources in cities. Investigates the nature of relations between built form and political purposes through close study of a wide variety of situations where public sector design commissions and planning processes have been clearly motivated by political pressures. Lectures and discussions focus on specific case studies of 20th-century government-sponsored designs carried out under diverse regimes in the US, Europe, and elsewhere.
L. Vale

11.303[J] Real Estate Development Studio: Complex Urban Projects
______

Graduate (Spring)
(Same subject as4.254[J])
Prereq: Permission of instructor
Units: 6-0-12
______
Focuses on the synthesis of projects for the real estate development industry, including the integration of physical design and programming with finance and marketing. Interdisciplinary student teams analyze how to maximize value in large-scale, mixed use projects in the process of preparing professional development proposals, involving sites in US cities and internationally. Reviews emerging real estate products and innovative developments to provide a foundation for studio work. Two major projects are interspersed with lectures, field trips, and short sketch exercises. Integrates skills and knowledge in the MSRED program; also open to other students interested in real estate development.
D. Frenchman, P. Roth

11.304[J] Site and Environmental Systems Planning
______

Graduate (Spring)
(Same subject as4.255[J])
Prereq: Permission of instructor
Units: 6-0-9
______
Introduces a range of practical approaches involved in evaluating and planning sites within the context of natural and cultural systems. Develops the knowledge and skills to analyze and plan a site for development through exercises and an urban design project. Topics include land inventory, urban form, spatial organization of uses, parcelization, design of roadways, grading, utility systems, off-site impacts, and landscape architecture.
M. A. Ocampo

11.307[J] Beijing Urban Design Studio
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as4.173[J])
Prereq: Permission of instructor
Units: 0-18-0
TBA.
______
Design studio that includes architects and city planners working in teams on a contemporary development project of importance in China. Students analyze conditions, explore alternatives, and synthesize architecture, city design, and implementation plans. Lectures and brief study tours expose students to history and contemporary issues of urbanism in China. Offered every other summer in residence at Tsinghua University, Beijing, involving students and faculty from both schools. Limited to 10.
D. Frenchman, C. Zegras
No textbook information available

11.308[J] Ecological Urbanism Seminar
______

Graduate (Fall)
(Same subject as4.213[J])
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4213
Lecture: M2-5 (10-401)
______
Examines the urban environment as a natural phenomenon, human habitat, medium of expression, and forum for action. Subject has two related, major themes: how ideas of nature influence the way cities are perceived, designed, built, and managed; and how natural processes and urban form interact and the consequences of these for human health safety and welfare. Enrollment limited.
A. Spirn
Textbooks (Fall 2016)

11.309[J] Sensing Place: Photography as Inquiry
______

Graduate (Fall)
(Same subject as4.215[J])
Prereq: None
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4215
Lecture: W EVE (2-6 PM) (10-485)
______
Explores photography as a disciplined way of seeing, of investigating urban landscapes and expressing ideas. Readings, observations, and photographs form the basis of discussions on light, detail, place, poetics, narrative, and how photography can inform design and planning. Enrollment limited.
A. Spirn
Textbooks (Fall 2016)

11.312 Engaging Community: Models and Methods for Designers and Planners
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Reviews a range of models for engaging communities, from a client-consultant relationship to advocacy, community organizing, consensus building, capacity building, and knowledge building. Explores the ways these different models have been used in design and planning practice and community building.
C. McDowell

11.313 Advanced Research Workshop in Landscape and Urbanism
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of Instructor
Units: 3-0-9
______
In-depth research workshop on pressing environmental design issue of our time, includes discussion and practices of various Landscape-based disciplines used to generate design-based solutions and landscape infrastructural responses to physical urban entropy and decline. Specific focus is adjusted each year.
A. Berger

11.314[J] Water, Landscape and Urban Design
______

Not offered academic year 2017-2018Graduate (Spring) Can be repeated for credit
(Same subject as4.214[J])
Prereq: Permission of instructor
Units: 3-3-6
______
Workshop surveys how water affects the design of buildings, landscapes and cities in aesthetic, functional and symbolic ways. Combines the systematic study of water issues with urban design projects in South Asia and the US. Covers topics such as rainwater harvesting, water use efficiency, wastewater reuse, stormwater management, floodplain design, constructed wetlands, and waterfront development. Students work together to integrate these design concepts at the site, urban, and international scales. Limited to 15.
J. Wescoat

11.315[J] Disaster Resilient Design
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as4.217[J])
Prereq: None
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Seminar examines the linkages between natural hazards and environmental design. Engages theoretical debates about landscapes of risk, vulnerability, and resilience. Participants generate proposals for disaster resilience through combinations of retrofit, reconstruction, resettlement, commemorative, and anticipatory design. Methods include rapid bibliographic search, risk analysis, landscape synthesis, and comparative international methods. Projects vary and may focus on current crises or involve collaboration with the Aga Khan Development Network and other humanitarian organizations. Limited to 15.
J. Wescoat

11.316[J] Landscape and Urban Heritage Conservation
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
(Same subject as4.216[J])
Prereq: Permission of instructor
Units: 3-3-6
______
Focuses on cultural landscape history, theory, and heritage issues and projects in the Indo-Islamic realm. Landscape and urban heritage inquiry go beyond monuments to encompass sites, cites, and regions. Combines the study of conservation theory and practice with an exploration of active urban landscape planning and design projects. Limited to 15.
J. Wescoat

11.318 Senseable Cities
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Studies how ubiquitous and real-time information technology can help us to understand and improve cities and regions. Explores the impact of integrating real-time information technology into the built environment. Introduces theoretical foundations of ubiquitous computing. Provides technical tools for tactile development of small-scale projects. Limited to 24.
C. Ratti

11.320 Digital City Design Workshop
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Students develop proposals, at the city and neighborhood scales, that integrate urban design, planning, and digital technology. Aims to create more efficient, responsive, and livable urban places and systems that combine physical form with digital media, sensing, communications, and data analysis. Students conduct field research, build project briefs, and deliver designs or prototypes, while supported by lectures, case studies, and involvement from experts and representatives of subject cities. Limited to 12.
D. Frenchman, C. Ratti

11.328[J] Urban Design Skills: Observing, Interpreting, and Representing the City
______

Graduate (Fall)
(Same subject as4.240[J])
Prereq: None
Units: 4-2-9
URL: http://architecture.mit.edu/subject/fall-2016-4240
Lecture: F9-1 (10-485) Recitation: W EVE (6-9 PM) (10-485)
______
Introduces methods of recording, evaluating, and representing the urban environment. Through visual observation, field analysis, measurements, interviews, and other means, students draw on their senses and develop their ability to deduce, conclude, question, and test conclusions about how the environment is used and valued. Using representational tools such as drawing, photographing, computer modeling and desktop publishing, students communicate what they observe along with their impressions and design ideas. Intended as a foundation for future studio work in urban design. Includes design-based projects.
E. Ben-Joseph
No required or recommended textbooks

11.330[J] The Making of Cities
______

Graduate (Spring)
(Same subject as4.241[J])
(Subject meets with4.251)
Prereq: 4.252 or 11.001
Units arranged
______
Examines the complex development of cities through history by tracing a diachronic accumulation of forms and spaces in specific cities, and showing how significant ideas were made manifest across distinct geographies and cultures. Emphasizes how economic, spiritual, political, geographic and technological forces have simultaneously shaped and, in turn, been influenced by the city. Additional work required of students taking graduate version.
L. Jacobi, R. Segal

11.332[J] Urban Design Studio
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as4.163[J])
Prereq: 4.162 or permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4163
Design: TR EVE (1-6 PM) (STUDIO)
______
The design of urban environments. Strategies for change in large areas of cities, to be developed over time, involving different actors. Fitting forms into natural, man-made, historical, and cultural contexts; enabling desirable activity patterns; conceptualizing built form; providing infrastructure and service systems; guiding the sensory character of development. Involves architecture and planning students in joint work; requires individual designs or design and planning guidelines.
M. Mazereeuw, A. Berger, F. Masoud
No textbook information available

11.333[J] Urban Design Seminar: Perspectives on Contemporary Practice
______

Graduate (Spring)
(Same subject as4.244[J])
Prereq: None
Units: 2-0-7
______
Examines innovations in urban design practice occurring through the work of leading practitioners in the fields of architecture, landscape architecture, and urban planning. Features lectures by major national and global practitioners in urban design. Projects and topics vary based on term and speakers but may cover architectural urbanism, landscape and ecology, arts and culture, urban design regulation and planning agencies, and citywide and regional design. Focuses on analysis and synthesis of themes discussed in presentations and discussions.
Staff

11.334[J] Advanced Seminar in Landscape and Urbanism
______

Graduate (Spring)
(Same subject as4.264[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Explores theories, practices, and emerging trends in the fields of landscape architecture and urbanism, such as systemic design, landscape urbanism, engineered nature, drosscapes, urban biodiversity, urban mobility, megaregions, and urban agriculture. Lectures, readings, and guest speakers present a wide array of multi-disciplinary topics, including current works from P-REX lab. Students conduct independent and group research that is future-oriented.
A. Berger

11.337[J] Urban Design Ideals and Action
______

Graduate (Spring)
(Same subject as4.247[J])
Prereq: 11.301 or permission of instructor
Units: 2-0-7
______
Examines the relationship between urban design ideals, urban design action, and the built environment through readings, discussions, presentations, and papers. Analyzes the diverse design ideals that influence cities and settlements, and investigates how urban designers use them to shape urban form. Provides a critical understanding of the diverse formal methods used to intervene creatively in both developed and developing contexts, especially pluralistic and informal built environments.
B. Ryan

11.338 Urban Design Studio
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 11.328
Units: 0-12-9
______
Examines the rehabilitation and re-imagination of a city. Analyzes the city at three scales: citywide, neighborhood, and individual dwellings. Aims to shape innovative design solutions, enhance social amenity, and improve economic equity through strategic and creative geographical, urban design and architectural thinking. Intended for students with backgrounds in architecture, community development, and physical planning. Limited to 12 via application and lottery.
B. Ryan

11.339 Downtown
______

Graduate (Spring)
(Subject meets with11.026[J],21H.321[J])
Prereq: None
Units: 2-0-7
______
Seminar on downtown in US cities from the late 19th century to the late 20th. Emphasis on downtown as an idea, place, and cluster of interests, on the changing character of downtown, and on recent efforts to rebuild it. Topics considered include subways, skyscrapers, highways, urban renewal, and retail centers. Focus on readings, discussions, and individual research projects. Students taking graduate version complete additional assignments.
R. M. Fogelson

11.342[J] Globalization and the Built Environment
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as1.463[J])
Prereq: Permission of instructor
Units: 2-0-4
______
Addresses the importance and pervasiveness of globalization in Architecture, Engineering and Construction Companies (AEC Firms). Covers strategies for a presence in the global market and the importance of the global financial market in project financing, with a primary focus on infrastructure. Includes discussion of innovative approaches to marketing, partnering, risk management, finance, specialized delivery systems, and privatization.
F. Moavenzadeh, D. Wolff

11.344[J] Innovative Project Delivery in the Public and Private Sectors
______

Graduate (Spring); first half of term
(Same subject as1.472[J])
Prereq: Permission of instructor
Units: 2-0-4
______
Develops a strong strategic understanding of how best to deliver various types of projects in the built environment. Examines the compatibility of various project delivery methods, consisting of organizations, contracts, and award methods, with certain types of projects and owners. Six methods examined: traditional general contracting; construction management; multiple primes; design-build; turnkey; and build-operate-transfer. Includes lectures, case studies, guest speakers, and a team project to analyze a case example.
C. M. Gordon

11.345[J] Entrepreneurship in Construction and Real Estate Development
______

Graduate (Fall); second half of term
(Same subject as1.462[J])
Prereq: Permission of instructor
Units: 2-0-4
Begins Oct 24. Lecture: R3-5.30 (9-354)
______
Develops skills necessary to incubate concepts for new real estate/built environment ventures and to evolve those ideas into viable startup ventures. Addresses the progression of an idea, from inception to opportunity to sustainable business. Students develop a business plan. Guest lecturers share their entrepreneurial paths and relevant experience. Explores the role of real estate developers in developing/emerging markets, with a focus on solving social development challenges, innovating new development strategies/products, and generating triple bottom-line returns with development projects.
J. F. Kennedy
Textbooks (Fall 2016)

11.351 Real Estate Ventures I: Negotiating Development-Phase Agreements
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Lecture: R EVE (6-9 PM) (9-354)
______
Focuses on key business and legal issues within the principal agreements used to control, entitle, capitalize, and construct a mixed-use real estate development. Through the lens of the real estate developer and its counter-parties, students identify, discuss, and negotiate the most important business issues in right of entry, purchase and sale, development, and joint-venture agreements, as well as a construction contract and construction loan agreement. Students work closely with attorneys who specialize in the construction of such agreements and with students from area law schools and Columbia University. Enrollment limited; preference to MSRED students. No listeners.
W. T. McGrath
No required or recommended textbooks

11.352 Real Estate Ventures II: Negotiating Leases, Financings, and Restructurings
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Focuses on key business and legal issues within the principal agreements used to lease, finance, and restructure a real estate venture. Through the lens of the real estate developer and its counter-parties, students identify, discuss and negotiate the most important business issues in office and retail leases, and permanent loan, mezzanine loan, inter-creditor, standstill/forbearance, and loan modification (workout) agreements. Students work closely with attorneys who specialize in the construction of such agreements and with students from area law schools and New York University. Single-asset real estate bankruptcy and the federal income tax consequences of debt restructuring are also addressed. Enrollment limited; preference to MSRED students; no Listeners.
W. T. McGrath

11.353[J] Securitization of Mortgages and Other Assets
______

Graduate (Spring)
(Same subject as15.429[J])
Prereq: 15.426, 15.401, or permission of instructor
Units: 3-0-6
______
Investigates the economics and finance of securitization, a practice that allows illiquid assets to be transformed into more liquid securities. Considers the basic mechanics of structuring deals for various asset-backed securities. Investigates the pricing of pooled assets, using Monte Carlo and other option pricing techniques, as well as various trading strategies used in these markets.
W. Torous

11.354 Real Estate Products Seminar
______

Graduate (Fall)
Prereq: None
Units: 3-0-3
Lecture: T1-2.30 (9-354)
______
Examines the fundamentals of real estate development products, including residential, hotel, office, research and development/lab, retail, and industrial uses. Includes faculty lectures, guest presentations, and field trips to local case study projects. Prepares MSRED candidates for the spring Real Estate Development Studio.
J. Cookke
No textbook information available

11.355 International Housing Economics and Finance
______

Graduate (Spring)
Prereq: 11.202, 11.203, 14.01 or permission of instructor
Units: 3-0-6
Credit cannot also be received for11.145
______
Presents a theory of comparative differences in international housing outcomes. Introduces institutional differences in the ways housing expenditures are financed, and the economic determinants of housing outcomes, such as construction costs, land values, housing quality, and ownership rates. Analyzes the flow of funds to and from the different national housing finance sectors. Develops an understanding of the greater financial and macroeconomic implications of the mortgage credit sector, and how policies affect the ways in which housing asset fluctuations impact national economies. Considers the perspective of investors in international real estate markets and the risks and rewards involved. Draws on lessons from an international comparative approach, and applies them to economic and finance policies at the local, state/provincial, and federal levels within a country of choice. Meets with 11.145 when offered concurrently. Students taking graduate version complete additional assignments.
A. Saiz

11.360 Community Growth and Land Use Planning
______

Graduate (Fall)
Prereq: Permission of Instructor
Units: 3-0-9
Lecture: TR2.30-4 (10-401)
______
Practicum workshop on strategies of planning and control for growth and land use, chiefly at the municipal level. Growth and its local consequences; land use planning approaches; implementation tools including innovative zoning and regulatory techniques, physical design, and natural systems integration. Semester-long projects arranged with student teams serving municipal clients. Preference to MCP second year students.
T. S. Szold
No required or recommended textbooks

11.364 International Environmental Treaties and Their Implementation
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 11.601, 11.255, or permission of instructor
Units: 3-0-6
______
Examines the history and dynamics of international environmental treaty-making, or what is called environmental diplomacy. Emphasis is on climate change and other atmospheric, marine resource, global waste management and sustainability-related treaties and the problems of implementing them. Reviews the legal, economic, and political dynamics of managing shared resources, involving civil society on a global basis, and enforcing transboundary agreements. Focuses especially on principles from international relations, international law, environmental management and negotiation theory as they relate to common-pool resource management.
L. Susskind

11.367 The Law and Politics of Land Use
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Analysis of local and state power to regulate land use and development. Particular emphasis on the evolution of planning and zoning regulations, and the perceived narrowing of the relationship between public improvements requirements and development impact. The ability of regulatory bodies to impose environmental performance standards and limit development activity is explored in relation to recent Supreme Court and State SJC decisions. Development decisions rendered by public agencies are reviewed, critiqued, and discussed.
T. S. Szold

11.368 Environmental Justice: Law and Policy
______

Not offered academic year 2017-2018Graduate (Fall)
(Subject meets with11.148)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: M2-5 (9-217)
______
Introduces frameworks for analyzing and addressing inequalities in the distribution of environmental benefits and burdens. Explores the foundations and principles of the environmental justice movement from the perspectives of social science, public policy, and law. Applies environmental justice principles to contemporary issues in urban policy and planning.
J. Steil
Textbooks (Fall 2016)

11.371[J] Sustainable Energy
______

Graduate (Fall)
(Same subject as1.818[J],2.65[J],10.391[J],22.811[J])
(Subject meets with2.650[J],10.291[J],22.081[J])
Prereq: Permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/10.391J/www/
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various energy technologies in each fuel cycle stage for fossil (oil, gas, synthetic), nuclear (fission and fusion) and renewable (solar, biomass, wind, hydro, and geothermal) energy types, along with storage, transmission, and conservation issues. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments.
M. W. Golay
Textbooks (Fall 2016)

11.373[J] Science, Politics, and Environmental Policy
______

Graduate (Fall)
(Same subject as12.885[J])
(Subject meets with12.385)
Prereq: Permission of instructor
Units: 3-0-6
Lecture: M EVE (3-6 PM) (54-1623)
______
Examines the role of science in US and international environmental policymaking. Surveys the methods by which scientists learn about the natural world; the treatment of science by experts, advocates, the media, and the public and the way science is used in legislative, administrative and judicial decision making. Through lectures, group discussions, and written essays, students develop a critical understanding of the role of science in environmental policy. Potential case studies include fisheries management, ozone depletion, global warming, smog, and endangered species. Students taking the graduate version complete different assignments.
S. Solomon, J. Knox-Hayes
No required or recommended textbooks

11.376 Urban Sustainability in Action
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Considers the theory and practice of urban sustainability. Introduces concepts of environmental sustainability, systems dynamics, ecological footprints, and environmental indicators. Investigates cutting-edge practices of cities in the US and around the world. Drawing on those examples, students work in and around the City of Boston on local sustainability initiatives.
Staff

11.377 Food Systems and the Environment
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
______
Explores the evolution of food production in the US and globally. Considers the science, economics, and politics behind the transition from pre-industrial to an industrial food system. Debates the costs and benefits of genetically modified food, organic agriculture, and local/regional food production. Focuses on the environmental sustainability and human-health consequences of different approaches, for both the developed and developing world.
Staff

11.378[J] Water Planning, Policy, and Design
______

Graduate (Fall) Can be repeated for credit
(Same subject as4.625[J])
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4625
Lecture: T9-12 (1-375) +final
______
Focuses on water in environmental planning, policy, and design. Draws together faculty and students who are working on water-related research projects to develop and maintain a current perspective on the field from the site to metropolitan and international scales. Limited to 15.
J. Wescoat
No textbook information available

11.380 Urban Climate Adaptation
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
______
Examines the challenges cities face and strategies to prepare for the impacts of climate change. Particular attention to the needs of vulnerable populations and resource-constrained cities, global and national adaptation policies and funding mechanisms, and ways in which local government and community-based activities can promote climate-readiness.
Staff

11.381 Infrastructure Systems in Theory and Practice
______

Graduate (Fall)
Prereq: 14.01; 11.202 or 11.203; or by permission of instructor
Units: 3-0-9
TBA.
______
Examines theories of infrastructure from science and technology studies, history, economics, and anthropology in order to understand the prospects for change for many new and existing infrastructure systems. Examines how these theories are then implemented within systems in the modern city, including but not limited to, energy, water, transportation, and telecommunications infrastructure. Seminar is conducted with intensive group research projects, in-class discussions and debates.
D. Hsu
No textbook information available

11.382 Water Diplomacy: The Science, Policy, & Politics of Managing Shared Resources
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Examines the history and dynamics of international environmental treaty-making, or what is called environmental diplomacy. Emphasizes climate change and other atmospheric, marine resource, global waste management and sustainability-related treaties and the problems of implementing them. Reviews the legal, economic, and political dynamics of managing shared resources, involving civil society on a global basis, and enforcing transboundary agreements. Focuses especially on principles from international relations, international law, environmental management, and negotiation theory as they relate to common-pool resource management.
L. Susskind

11.383[J] Managing Sustainable Businesses for People and Profits
______

Graduate (Spring)
(Same subject as15.662[J])
Prereq: None
Units: 3-6-3
______
Examines opportunities and challenges involved in building and growing businesses that achieve high financial performance and provide good jobs and careers to employees. Students engage participants in the MITx online course title Shaping the Future of Work to learn about the expectations and employment experiences of workers across the world. Through readings, cases, simulations and class visits from industry leaders, explores the underlying principles and business practices that help to secure that alignment between business health and societal well-being.
T. Kochan

11.384 Preparation for Malaysia Sustainable Cities Fieldwork
______

Graduate (Fall); partial term
Prereq: Permission of instructor
Units: 0-0-3 [P/D/F]
TBA.
______
Under faculty supervision, students conduct independent research to familiarize themselves with the culture, economy, politics, geography, ecology, and history of Malaysia. Selection by application.
L. Susskind
No textbook information available

11.385 Malaysia Sustainable Cities Fieldwork
______

Graduate (IAP)
Prereq: 11.384
Units: 3-0-3 [P/D/F]
______
Investigates sustainable development efforts of regional development agencies in Penang, Kuala Lumpur, or Johor Bahru. In addition to these sites, students visit the government city of Putrajaya, the World Heritage cities of George Town in Penang and Malacca, and Kuching in East Malaysia. Selection by application.
L. Susskind

11.386 Malaysia Sustainable Cities Practicum
______

Graduate (Spring); partial term
Prereq: 11.385
Units: 2-0-1
______
Examines examples of city development that reflect a commitment to the principles of sustainability, including economic development that ensures ecological sustainability, strategies for addressing intercultural tensions, and environmental quality improvements catalyzed by city development.
L. Susskind

11.401 Introduction to Housing, Community and Economic Development
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Lecture: TR9.30-11 (9-451)
______
Provides a critical introduction to the shape and determinants of political, social and economic inequality in America. Explores equitable development as a response framework for planners; social capital and community building as planning concepts; and the history, development, and current prospects of the fields of housing (with an emphasis on affordability and inclusion) and local economic development. Considers multiple scales but primarily the neighborhood, city/town, and metro region, centered on the interplay of policies, institutions and markets.
J. Steil
Textbooks (Fall 2016)

11.402 Urban Politics: Race and Political Change
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: None
Units: 3-0-9
______
Examines the place of US cities in political theory and practice. Particular attention given to contemporary issues of racial polarization, demographic change, poverty, sprawl, and globalization. Specific cities are a focus for discussion.
J. P. Thompson

11.404 Housing Policy and Planning in the US and Abroad
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Explores the policy tools and planning techniques used to formulate and implement housing strategies at local, state and federal levels. Topics include America's housing finance system and the causes of instability in mortgage markets; economic and social inequity in access to affordable housing; approaches to meeting community housing needs through local and state planning programs; programs for addressing homelessness; and emerging ideas about sustainable development and green building related to housing development and renovation. Introduces comparative policy approaches from other countries.
J. Buckley

11.405 Political Economy & Society
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of Instructor
Units: 3-0-6
______
Focuses on the connection (or not) between mind (theory) and matter (lived experience). Examines basic tenets of classical and recent political economic theories and their explication in ideas of market economies, centrally planned economies, social market economies, and co-creative economies. Assesses theories according to their relation to the lived experiences of people in communities and workplaces.
J. P. Thompson

11.406 Key Ideas in City Planning History and Theory
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
TBA.
______
Investigates the evolution of the ideals, the profession, and the practice of city planning throughout history by looking at key ideas that have driven theorists and practitioners. Explores city and regional planning in the light of broader historical trends, such as changing ideas about who cities are for; different approaches to urban problem-solving; variable factors affecting how urban settlements should be organized and re-organized; the development of human understanding about relationships between the built and natural environments; and about the effects of urban form and organization on society. Focuses substantially but not entirely upon the American experience.
Staff
No textbook information available

11.407 Economic Development Tools and Techniques
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR11-12.30 (9-451)
______
Introduces a suite of tools representing the basic set of practices used in the development field. Presents a wealth creation framework that focuses on place, improving livelihoods, incentivizing collaboration, creating multiple forms of wealth, and promoting local ownership. Students work with web-based tools designed for use in a professional setting. Discussions are based on results from tools, their interpretation, and their meaning. Relevant to all students interested in the structure and function of local, state, national and international economic contexts. Students develop a series of memos as students they complete assignments.
A. Glasmeier
No textbook information available

11.427[J] Urban Labor Markets and Employment Policy
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as15.677[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Discusses the broader trends in the labor market, how urban labor markets function, public and private training policy, other labor market programs, the link between labor market policy and economic development, and the organization of work within firms.
P. Osterman

11.430[J] Leadership in Real Estate
______

Graduate (Fall); first half of term
(Same subject as15.941[J])
Prereq: None
Units: 3-0-3
Ends Oct 21. Lecture: MW10.30-12 (9-357)
______
Designed to help students deepen their understanding of leadership and increase self-awareness. They examine authentic leadership styles and create goals and a learning plan to develop their capabilities. They also participate in activities to strengthen their "leadership presence" - the ability to authentically connect with people's hearts and minds. Students converse with leaders to learn from their insights, experiences, and advice. Limited to 15.
G. Schuck
Textbooks (Fall 2016)

11.431[J] Real Estate Finance and Investment
______

Graduate (Fall)
(Same subject as15.426[J])
Prereq: Permission of instructor
Units: 4-0-8
Lecture: MW4-5.30 (9-354) Recitation: M EVE (5.30-7 PM) (9-354)
______
Concepts and techniques for analyzing financial decisions in commercial property development and investment. Topics include property income streams, urban economics, discounted cash flow, equity valuation, leverage and income tax considerations, development projects, and joint ventures.
D. Geltner
Textbooks (Fall 2016)

11.432[J] Real Estate Capital Markets
______

Graduate (Spring); first half of term
(Same subject as15.427[J])
Prereq: 11.431; 15.402 or 15.414
Units: 2-0-4
______
Introduces real estate capital markets for institutional investors. Topics include real estate investment trusts (REIT), commercial mortgage-backed securities (CMBS), and private equity. Concepts and techniques for investment analysis include portfolio theory and equilibrium asset pricing. Additional topics may include price indexing and derivatives.
D. Geltner

11.433[J] Real Estate Economics
______

Graduate (Fall)
(Same subject as15.021[J])
Prereq: 14.01, 15.010, or 15.011
Units: 4-0-8
Lecture: TR11-12.30 (4-270) Recitation: M9-10.30 (9-354) +final
______
Develops understanding of the fundamental economic factors that shape the market for real property, as well as the influence of capital markets in asset pricing. Analyzes of housing as well as commercial real estate. Covers demographic analysis, regional growth, construction cycles, urban land markets, and location theory. Exercises and modeling techniques for measuring and predicting property demand, supply, vacancy, and prices.
W. C. Wheaton
Textbooks (Fall 2016)

11.434[J] Tools for Analysis: Design for Real Estate and Infrastructure Development
______

Graduate (Spring); second half of term
(Same subject as15.428[J],IDS.671[J])
Prereq: None
Units: 2-0-4
______
Introduction to analytical tools to support design and decision-making in real estate, infrastructure development, and investment. Particular focus on identifying and valuing sources of flexibility using "real options," Monte-Carlo simulation, and other techniques from the field of engineering systems. Integrates economic and engineering perspectives, and is suitable for students with various backgrounds. Provides useful preparation for thesis work in the area.
D. Geltner, R. de Neufville

11.435 Mixed-Income Housing Development
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Lecture: MW2.30-4 (9-357)
______
Provides an overview of affordable and mixed-income housing development for students who wish to understand the fundamental issues and requirements of urban scale housing development, and the process of planning, financing and developing such housing. Students gain practical experience assembling a mixed-income housing development proposal.
P. Roth
No textbook information available

11.436 Housing Studio: Neighborhood Sustainability Plan
______

Graduate (Spring)
Prereq: 11.401, 11.301, or 11.601
Units: 6-0-9
______
Explores ways to improve housing quality and affordability, increase energy savings, and promote transportation access as part of a neighborhood sustainability plan. Students work with a local client to define the terms of local sustainability for a specific Boston neighborhood, then design an appropriate framework for action for the target site focusing on existing and future housing needs, community services, transit connections, and energy policy.
Staff

11.437 Financing Economic Development
______

Graduate (Fall)
(Subject meets with11.137)
Prereq: None
Units: 4-0-8
Lecture: MW11-12.30 (8-205) Recitation: F1.30 (10-401)
______
Focuses on financing tools and program models to support local economic development. Provides an overview of private capital markets and financing sources to understand capital market imperfections that constrain economic development, business accounting, financial statement analysis, federal economic development programs, and public finance tools. Covers policies and program models, including revolving loan funds, guarantee programs, venture capital funds, bank holding companies, community development loan funds and credit unions, micro enterprise funds, and the Community Reinvestment Act. Students taking graduate version complete additional assignments. Limited to 25.
K. Seidman
Textbooks (Fall 2016)

11.438 Economic Development Planning
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 11.203, 11.220
Units: 3-0-9
______
Focuses on the policy tools and planning techniques used to formulate and implement local economic development strategies. Includes an overview of economic development theory, discussion of major policy areas and practices employed to influence local economic development, a review of analytic tools to assess local economies and how to formulate strategy. Coursework includes formulation of a local economic development strategy for a client.
K. Seidman

11.439 Revitalizing Urban Main Streets
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 11.401 or 11.301J or 11.328J
Units: 4-0-11
______
Workshop explores the integration of economic development and physical planning interventions to revitalize urban commercial districts. Covers: an overview of the causes of urban business district decline, revitalization challenges, and the strategies to address them; the planning tools used to understand and assess urban Main Streets from both physical design and economic development perspectives; and the policies, interventions, and investments used to foster urban commercial revitalization. Students apply the theories, tools and interventions discussed in class to preparing a formal neighborhood commercial revitalization plan for a client business district.
K. Seidman, S. Silberberg

11.444[J] The New Global Planning Practitioner
______

Graduate (Spring)
(Same subject as4.232[J])
(Subject meets with4.233)
Prereq: Permission of instructor
Units: 3-0-6
______
Considers a new interdisciplinary paradigm of practice that regards dialogue among practitioners and users essential for efficacious and creative design and planning process. Focuses on non-traditional client groups: communities, the poor, and the generally excluded middle-income. Explores key issues confronting development practitioners, with stress on practical exercises drawn from current national and international case studies; e.g., an investigative comparison of cities or tools in coping with impending rapid and massive growth and expansion. Engages those with a design and community service orientation. Additional work required of students taking the graduate version.
R. Goethert

11.450 Real Estate Development Building Systems
(New)
______

Graduate (Fall); first half of term
Prereq: None
Units: 2-0-1
Ends Oct 21. Lecture: R3-5 (9-354)
______
Provides students with a concise overview of the range of building systems that are encountered in professional commercial real estate development practice in the USA. Focuses on the relationship between real estate product types, building systems, and the factors that real estate development professionals must consider when evaluating these products and systems for a specific development project. Surveys commercial building technology including Foundation, Structural, MEP/FP, Envelope, and Interiors systems and analyzes the factors that lead development professionals to select specific systems for specific product types. One or more field trips to active construction sites may be scheduled during non-class hours based on student availability.
Y. Tsipis
No required or recommended textbooks

11.457 More than Data: Smart Cities, Big Data, Civic Technology and Policy
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: None
Units: 3-0-6
______
Discussions of future directions in the 'smart cities' debate. Begins by framing the current smart city with past trends such as the efficient city movement of the 1930s and the Modernist city of the 1950s and 60s. Examines current trends in big data, civic apps, Code for America, the open data movement, DIY data collections devices, and their policy impacts.
S. Williams

11.458 Crowd Sourced City: Civic Tech Prototyping Class
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Investigates the use of social medial and digital technologies for planning and advocacy by working with actual planning and advocacy organizations to develop, implement, and evaluate prototype digital tools. Students use the development of their digital tools as a way to investigate new media technologies that can be used for planning.
S. Williams

11.461[J] Technocracy
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject asSTS.463[J])
Prereq: None
Units: 3-0-9
______
Survey of the history of efforts to apply scientific methods and technological tools to solve social and political problems, with a focus on the United States since 1850. Topics include: city planning, natural resource management, public education, economic development, quantification and modeling in the social and policy sciences, technology transfer, and political economies of expertise.
J. S. Light

11.463[J] Structuring Low-Income Housing Projects in Developing Countries
______

Graduate (Fall)
(Same subject as4.236[J])
Prereq: Permission of instructor
Units: 3-0-9
URL: http://architecture.mit.edu/subject/fall-2016-4236
Lecture: R9-12 (1-375) +final
______
Examines dynamic relationship among key actors: beneficiaries, government, and funder. Emphasis on cost recovery, affordability, replicability, user selection, and project administration. Extensive case examples provide basis for comparisons.
R. Goethert
No required or recommended textbooks

11.466[J] Technology, Globalization, and Sustainable Development
______

Graduate (Fall)
(Same subject as1.813[J],15.657[J],IDS.437[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: W EVE (4-6.30 PM) (E51-376)
______
Investigates sustainable development, taking a broad view to include not only a healthy economic base, but also a sound environment, stable employment, adequate purchasing power, distributional equity, national self-reliance, and maintenance of cultural integrity. Explores national, multinational, and international political and legal mechanisms to further sustainable development through transformation of the industrial state. Addresses the importance of technological innovation and the financial crisis of 2008.
N. Ashford
Textbooks (Fall 2016)

11.468[J] SIGUS Workshop
______

Graduate (Fall, IAP) Can be repeated for credit
(Same subject as4.230[J])
(Subject meets with4.231)
Prereq: Permission of instructor
Units arranged
URL: http://architecture.mit.edu/subject/fall-2016-4230
Lecture: W EVE (5-6.30 PM) (2-103)
______
Interdisciplinary projects and interactive practices in urban settlement issues as investigated by MIT's SIGUS (Special Interest Group in Urban Settlements), with a focus on developing countries throughout the world. Participation by guest practitioners. Additional work required of students taking the graduate version.
R. Goethert
No required or recommended textbooks

11.469 Urban Sociology in Theory and Practice
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Introduction to core writings in urban sociology. Examines key theoretical paradigms that have comprised the field since its founding. Explores the nature and changing character of the city and the urban experience in the US and abroad, providing context for development and application of planning skills and sensibilities as well as urban research. Topics include the changing nature of community, social inequality, culture, political power, socio-spatial change, technological change, and the relationship between the built environment and human behavior.
J. Steil

11.470 The Politics of Development Policy
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Examines the political forces and conditions that affect urban, regional, and national development policymaking. Key protagonists include political parties, state actors, social movements, NGOs (domestic and global), business groups, and labor organizations, both formal and informal. Primary emphasis is the developing world, but seeks parallels across a variety of comparative and historical contexts.
Staff

11.472[J] D-Lab: Development
______

Graduate (Fall)
(Same subject asEC.781[J])
(Subject meets with11.025[J],EC.701[J])
Prereq: None
Units: 3-2-7
Lecture: MWF3.30-5 (N51-310)
______
Issues in international development, appropriate technology and project implementation addressed through lectures, case studies, guest speakers and laboratory exercises. Students form project teams to partner with community organizations in developing countries, and formulate plans for an optional IAP site visit. (Previous field sites include Ghana, Brazil, Honduras and India.) Recitation sections focus on specific project implementation, and include cultural, social, political, environmental and economic overviews of the target countries as well as an introduction to the local languages. Enrollment limited by lottery; must attend first class session.
S. L. Hsu, A. B. Smith, B. Sanyal
No textbook information available

11.474 D-Lab: Disseminating Water, Sanitation and Hygiene Innovations for the Common Good
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets withEC.715)
Prereq: None
Units: 3-0-6
______
Focuses on disseminating water, sanitation and hygiene (WASH) innovations in developing countries, especially among underserved communities. Structured around field-based learning, case studies, lectures and videos. Emphasis on core WASH principles, culture-specific solutions, appropriate and sustainable technologies, behavior change, social marketing and building partnerships. Term project entails implementing the "next steps" in a WASH innovation in a specific locale and/or a new proposal/plan/project. Long-term commitment to specific real-world WASH projects which have been disseminated by MIT faculty, students and alumni. Students taking graduate version complete additional assignments. Limited to 30.
S. E. Murcott

11.475 Navigating Power in Water and Sanitation Planning
______

Graduate (Spring)
Prereq: Open to undergraduates with permission of instructor
Units: 3-0-9
______
Informs and prepares students to navigate the explicit and implicit power dynamics among stakeholders in decision-making processes that govern the planning and delivery of water and sanitation systems. Through investigations of organization, regulation, financing, physical delivery, and research designs, students examine the trajectory of decisions that shape and influence the accessibility, affordability, and adequacy of water and sanitation services, particularly in vulnerable neighborhoods in mostly urban and peri-urban areas. Emphasis is placed on the importance of moving beyond the limited dimensions of supply and demand studies and gaining fluency in the multiplicative political-economic and social factors driving choices in water and sanitation systems planning. In-depth, globally comparative readings inform the course, and expose basic services in water and sanitation as a misnomer.
G. Carolini

11.476 Urbanizing China
______

Graduate (Fall)
Not offered regularly; consult department
(Subject meets with11.146)
Prereq: Permission of instructor
Units: 2-0-7
URL: http://dusp.mit.edu/subject/fall-2014-11s945
______
Discusses China's daunting urban challenges: congestion and smog, housing affordability, land reform and urban financing, migrants and locals, and social and spatial inequality. Provides examples of laudable achievements and diverse and innovative responses across more than six hundred cities. Presents China's urbanization as the joint result of natural socioeconomic processes and conscious actions by governments, markets, and the public. Presents multidisciplinary approaches and alternative narratives. Examines the intricate interaction between state and market in China's context, yielding a variety of state-market 'cocktails' devised and experimented in different cities in response to local problems, each involving a multilayered projection onto urban space. Students taking graduate version complete additional assignments.
J. Zhao

11.477[J] Urban Energy Systems and Policy
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as1.286[J])
(Subject meets with11.165)
Prereq: 11.203, 14.01, or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Examines efforts in developing and advanced nations and regions. Examines key issues in the current and future development of urban energy systems, such as technology, use, behavior, regulation, climate change, and lack of access or energy poverty. Case studies on a diverse sampling of cities explore how prospective technologies and policies can be implemented. Includes intensive group research projects, discussion, and debate.
D. Hsu

11.478 Behavior and Policy: Connections in Transportation
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Examines the behavioral foundation for policy design, using urban transportation examples. Introduces multiple frameworks of understanding behavior, contrasting perspectives of classic economic theory with behavioral economics and social psychology, suggests corresponding policy interventions and establishes a mapping between behavior, theory, and policy. Presents a spectrum of instruments for positively influencing behavior and improving welfare. Challenges students to critique, design, implement and interpret experiments that nudge travel behavior. Brings behavioral insights to creative design of transport policies that are efficient and equitable as well as simple, consistent, transparent, acceptable, and adaptive to behavioral changes.
J. Zhao

11.479[J] Water, Sanitation, Hygiene and Environmental Sanitation (WASH-ENV) in Low- and Middle-income Countries
______

Graduate (Spring)
(Same subject as1.851[J])
Prereq: None
Units arranged
______
Addresses principles and practice of water, sanitation, hygiene and environmental sanitation (WASH-ENV) systems, infrastructure, engineering, and planning in low- and middle-income countries. Incorporates interdisciplinary technical, socio-cultural, public health, human rights, behavioral, and economic aspects into the design and implementation of interventions. Students develop skills to plan simple, yet reliable, WASH-ENV systems together with urban or rural communities that are compatible with local customs and available human and material resources.
Staff

11.480 Urbanization and Development
______

Graduate (Spring)
(Subject meets with11.140)
Prereq: None
Units: 3-0-9
______
Examines developmental dynamics of rapidly urbanizing locales, with a special focus on the developing world. Case studies from India, China, Mexico, Brazil, and South Africa form the basis for discussion of social, spatial, political and economic changes in cities spurred by the decline of industry, the rise of services, and the proliferation of urban mega projects. Emphasizes the challenges of growing urban inequality, environmental risk, citizen displacement, insufficient housing, and the lack of effective institutions for metropolitan governance. Students taking graduate version complete additional assignments.
Staff

11.481[J] Analyzing and Accounting for Regional Economic Change
______

Graduate (Spring)
(Same subject as1.284[J])
Prereq: 14.03, 14.04
Units: 3-0-9
______
Surveys theories of regional growth, factor mobility, clustering, industrial restructuring, learning regions, and global supply chains from a political-economy perspective. Examines/critiques multipliers, linkages, and supply chains used to assess employment and environmental impacts, energy and infrastructure investments, and accounting issues related to the underground economy, work in the home, and environmental degradation. Assesses price indices, industrial location and employment measures, and shift-share analyses. Discussions of US and foreign applications.
Staff

11.482[J] Regional Socioeconomic Impact Analyses and Modeling
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as1.285[J])
Prereq: 11.481J or permission of instructor
Units: 2-1-9
URL: http://web.mit.edu/11.482/www/Syllabus482-2001.html
______
Reviews regional economic theories and models and provides students with experience in using alternative economic impact assessment models on microcomputers. Problem sets are oriented around infrastructure, housing, energy, and environmental issues. Students work with a client generally in Boston and make a presentation to the client. Emphasis on written and oral presentation skills.
K. R. Polenske

11.483 Housing and Land Use in Rapidly Urbanizing Regions
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Studies current urban controversies over affordable housing, land redevelopment, and public space, with special attention to property rights. Reviews how law, economics, sociology and planning theories frame these issues and interplays them with spatial approaches of urban design and geography. Explores cases that use property rights strategies to increase economic growth and social justice, providing insight for future design and policymaking. Topics include land trusts for affordable housing, mixed-use public space, and critical cartography.
Y. Hong

11.484 Project Appraisal in Developing Countries
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with11.144)
Prereq: Permission of instructor
Units: 3-0-9
______
Covers techniques of financial analysis of investment expenditures, as well as the economic and distributive appraisal of development projects. Critical analysis of these tools in the political economy of international development is discussed. Topics include appraisal's role in the project cycle, planning under conditions of uncertainty, constraints in data quality and the limits of rational analysis, and the coordination of an interdisciplinary appraisal team. Students taking graduate version complete additional assignments. Enrollment limited; preference to majors.
Y. Hong

11.487 Budgeting and Finance for the Public Sector
______

Graduate (Spring)
(Subject meets with11.147)
Prereq: None
Units: 3-0-9
______
Examines globally relevant challenges of adequately and effectively attending to public sector responsibilities for basic services with limited resources. Particular attention to the contexts of fiscal crises and rapid population growth, as well as shrinkage, through an introduction to methods and processes of budgeting, accounting, and financial mobilization. Case studies and practice exercises explore revenue strategies, demonstrate fiscal analytical competencies, and familiarize students with pioneering examples of promising budget and accounting processes and innovative funding mobilization via taxation, capital markets, and other mechanisms (e.g., land-value capture). Students taking graduate version explore the subject in greater depth.
G. Carolini

11.488 Urban Development in Conflict Cities: Planning Challenges and Policy Innovations
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of Instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Economic, religious, gender and ethnic differences must be negotiated every day in the urban arena. When tensions and conflict escalates into violence, the urban space becomes the battlespace in which these tensions are negotiated. Examines urban development challenges in conflict cities through multiple disciplinary perspectives on urban conflict. Review of the literature about when violence and cities intersect. Focuses on policy innovations, and an examination of potential planning, design, and policy solutions.
Staff

11.490 Law and Development
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 2-0-10
______
Examines the role of law in development and introduces economic and legal theories. Topics include formality/informality of property, contracts and bargaining in the shadow of the law, institutions for transparency and accountability, legitimation of law, sequencing of legal reform, and international economic law aspects. Studies the roles of property rights in economic development, the judiciary and the bureaucracy in development, and law in aid policy. Includes selected country case studies. Limited to 15.
B. Rajagopal

11.491[J] Economic Development and Policy Analysis
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as17.176[J])
Prereq: 11.701
Units: 3-0-9
______
Examines the process of economic development to understand why some countries or regions within countries have increased their incomes and reduced their poverty faster than others. Economic development is treated as a process of learning, as countries weigh theories and role models as guides for policy formulation and institution building. Historical and empirical examination of three role models for development/underdevelopment, as formulated by the Third World's new intelligentsia that emerged after de-colonization: the OPEC development role model, the East Asian role model, and the Brazilian role model.
Staff

11.493 Property and Land Use Law for Planners
______

Not offered academic year 2017-2018Graduate (Fall)
(Subject meets with11.183)
Prereq: None
Units: 3-0-9
Lecture: W2-5 (9-450B)
______
Examines legal and institutional arrangements for the establishment, transfer, and control over property under American and selected comparative systems including India and South Africa. Focuses on key issues of property and land use law regarding planning and economic development. Emphasizes just and efficient resource use; institutional, entitlement and social relational approaches to property; distributional and other social aspects; and the relationship between property, culture, and democracy. Students taking graduate version complete additional assignments.
B. Rajagopal
No textbook information available

11.495 Governance and Law in Developing Countries
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 2-0-10
______
Examines the multiple dimensions of governance in international development with a focus on the role of legal norms and institutions in the balance between state and the market. Analyzes changes in the distribution of political and legal authority as a result of economic globalization. Topics include the regulation of firms; forms of state and non-state monitoring; varieties of capitalism, global governance and development; and good governance, including transparency and accountability mechanisms, the role of the judiciary and legal culture, and tools for measuring governance performance.
B. Rajagopal

11.496 Law, Social Movements, and Public Policy: Comparative and International Experience
______

Graduate (Spring)
(Subject meets with11.166)
Prereq: Permission of instructor
Units: 3-0-9
______
Studies the interaction between law, courts, and social movements in shaping domestic and global public policy. Examines how groups mobilize to use law to affect change and why they succeed and fail. Case studies explore the interplay between law, social movements, and public policy in current issues, such as gender, race, labor, trade, climate change/environment, and LGBTQ rights. Introduces theories of public policy, social movements, law and society, and transnational studies. Students taking graduate version complete additional assignments. Limited to 15.
B. Rajagopal

11.497 Human Rights at Home and Abroad
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with11.164[J],17.391[J])
Prereq: None
Units: 3-0-9
______
Provides a rigorous and critical introduction to the history, foundation, structure, and operation of the human rights movement. Focuses on key ideas, actors, methods and sources, and critically evaluates the field. Addresses current debates in human rights, including the relationship with security, democracy, development and globalization, urbanization, equality (in housing and other economic and social rights; women's rights; ethnic, religious and racial discrimination; and policing/conflict), post-conflict rebuilding and transitional justice, and technology-related issues. Students taking graduate version expected to write a research paper.
B. Rajagopal

11.520 Workshop on Geographic Information Systems
______

Graduate (Fall, Spring); partial term
Prereq: 11.205 or permission of instructor
Units: 2-2-2
Begins Oct 31. Lecture: MW2.30-4 (9-354) Lab: M EVE (5-7 PM) (W31-301) or T EVE (5-7 PM) (W31-301) or W EVE (5-7 PM) (W31-301) or R EVE (5-7 PM) (W31-301)
______
An introduction to geographic information systems (GIS) as applied to urban and regional planning, community development, and local government. Emphasis on learning GIS technology and spatial analysis techniques through extensive hands-on exercises using real-world data sets such as the US census of population and housing. Includes a small project on an urban planning problem involving the selection of appropriate methods, the use of primary and secondary data, computer-based modeling, and spatial analysis. Enrollment limited; preference to MCP students.
Fall:S. Williams
Spring:J. Ferreira
No textbook information available

11.521 Spatial Database Management and Advanced Geographic Information Systems
______

Graduate (Spring)
Prereq: Permission of instructor; or 11.520 andCoreq: 11.220
Units: 3-3-6
Credit cannot also be received for11.523,11.524
______
Extends the computing and geographic information systems (GIS) skills developed in 11.520 to include spatial data management in client/server environments and advanced GIS techniques. First half covers the content of 11.523, introducing database management concepts, SQL (Structured Query Language), and enterprise-class database management software. Second half explores advanced features and the customization features of GIS software that perform analyses for decision support that go beyond basic thematic mapping. Includes the half-term GIS project of 11.524 that studies a real-world planning issue.
J. Ferreira

11.522 Research Seminar on Urban Information Systems
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: 11.521 or permission of instructor
Units: 2-4-6
______
Advanced research seminar enhances computer and analytic skills developed in other subjects in this sequence. Students present a structured discussion of journal articles representative of their current research interests involving urban information systems and complete a short research project. Suggested research projects include topics related to ongoing UIS Group research.
J. Ferreira

11.523 Fundamentals of Spatial Database Management
______

Graduate (Spring); first half of term
Prereq: Permission of instructor
Units: 2-2-2
Credit cannot also be received for11.521,11.524
______
The fundamentals of database management systems as applied to spatial analysis. Includes extensive hands-on exercises using real-world planning data. Introduces database management concepts, SQL (Structured Query Language), and enterprise-class database software. Same content as first half of 11.521.
J. Ferreira

11.524 Advanced Geographic Information System Project
______

Graduate (Spring) Can be repeated for credit; second half of term
Prereq: 11.523 or permission of instructor
Units arranged
Credit cannot also be received for11.521,11.523
______
Learning and utilizing advanced geographic information system techniques in studio/lab setting with real-world client problem and complex digital spatial data infrastructure. Projects typically use the client and infrastructure setting for 11.521. Credit cannot also be received for 11.521 in the same term.
J. Ferreira

11.526[J] Comparative Land Use and Transportation Planning
______

Graduate (Spring)
(Same subject as1.251[J])
Prereq: Permission of Instructor
Units: 3-0-9
______
Focuses on the integration of land use and transportation planning, drawing from cases in both industrialized and developing countries. Reviews underlying theories, analytical techniques, and the empirical evidence of the land use-transportation relationship at the metropolitan, intra-metropolitan, and micro-scales. Also covers the various ways of measuring urban structure, form, and the "built environment." Develops students' skills to assess relevant policies, interventions and impacts.
C. Zegras

11.527 Advanced Seminar in Transportation Finance
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 2-1-9
______
Focuses on the theory and practice of transportation system finance, examining the range of relevant topics including basic public finance, politics, institutional structures, externalities, pricing, and the role of advanced technologies. Primarily oriented around land-based, surface transportation, although in their research students are welcome to examine air and maritime modes according to their interests. Explores issues across a range of contexts, including North America, Europe, Latin America, and Asia.
C. Zegras

11.533 Ecological Planning with GIS
______

Graduate (Spring)
Prereq: 11.205
Units: 3-3-6
______
Provides a practical introduction to spatial environmental assessment and planning methods, from landscape to regional scales. Lectures and discussions focus on key concepts in landscape ecology as well as the data and methods needed to incorporate these concepts in environmental planning. Weekly lab exercises demonstrate how natural systems are represented in modern geographic information systems, how to synthesize information using overlay analysis and suitability modeling, and design methods that build on the resulting syntheses. Features raster GIS analysis methods.
Staff

11.540[J] Urban Transportation Planning
______

Graduate (Fall)
(Same subject as1.252[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: F2-5 (5-217)
______
Studies the history, policy, practice and politics of urban transportation. Covers the role of the federal, state, and local government and the MPO, public transit in the auto era, analysis of current trends and pattern breaks; analytical tools for transportation planning, traffic engineering and policy analysis; the contribution of transportation to air pollution, social costs and climate change; land use and transportation interactions; traffic and place making; bicycles, pedestrians, and traffic calming. Examples from the Boston area and from Bilbao.
F. Salvucci, M. Murga
No textbook information available

11.541[J] Public Transportation Systems
______

Graduate (Spring)
(Same subject as1.258[J])
Prereq: 1.201 or permission of instructor
Units: 3-0-9
______
Discusses evolution and role of urban public transportation modes, systems and services, focusing on bus and rail. Describes technological characteristics and their impacts on capacity, service quality, and cost. Current practice and new methods for data collection and analysis, performance monitoring, route and network design, frequency determination, and vehicle and crew scheduling. Effect of pricing policy and service quality on ridership. Methods for estimating costs associated with proposed service changes. Organizational models for delivering public transportation service including finance and operations.
Staff

11.543[J] Transportation Policy, the Environment, and Livable Communities
______

Graduate (Spring)
(Same subject as1.253[J])
(Subject meets with1.153)
Prereq: Permission of instructor
Units: 3-0-9
______
Examines the economic and political conflict between transportation and the environment. Investigates the role of government regulation, green business and transportation policy as a facilitator of economic development and environmental sustainability. Analyzes a variety of international policy problems, including government-business relations, the role of interest groups, non-governmental organizations, and the public and media in the regulation of the automobile; sustainable development; global warming; politics of risk and siting of transport facilities; environmental justice; equity; as well as transportation and public health in the urban metropolis. Provides students with an opportunity to apply transportation and planning methods to develop policy alternatives in the context of environmental politics. Students taking graduate version complete additional assignments.
J. Coughlin

11.544[J] Transportation Systems Analysis: Performance and Optimization
______

Graduate (Fall)
(Same subject as1.200[J])
Prereq: 1.010, permission of instructor
Units: 3-1-8
Lecture: TR10.30-12 (3-370) Recitation: R4 (3-370)
______
Problem-motivated introduction to methods, models and tools for the analysis and design of transportation networks including their planning, operations and control. Capacity of critical elements of transportation networks. Traffic flows and deterministic and probabilistic delay models. Formulation of optimization models for planning and scheduling of freight, transit and airline systems, and their solution using software packages. User- and system-optimal traffic assignment. Control of traffic flows on highways, urban grids, and airspace.
C. Osorio
No required or recommended textbooks

11.545[J] Transportation Systems Analysis: Demand and Economics
______

Graduate (Fall)
(Same subject as1.201[J])
Prereq: Permission of instructor
Units: 3-1-8
Lecture: TR2.30-4 (2-105) Recitation: F11 (2-105) +final
______
Covers the key principles governing transportation systems planning and management. Introduces the microeconomic concepts central to transportation systems. Topics include economic theories of the firm, consumer, and market, demand models, discrete choice analysis, cost models and production functions, and pricing theory. Applications to transportation systems - including congestion pricing, technological change, resource allocation, market structure and regulation, revenue forecasting, public and private transportation finance, and project evaluation - cover urban passenger transportation, freight, maritime, aviation, and intelligent transportation systems.
Staff
Textbooks (Fall 2016)

11.601 Introduction to Environmental Policy and Planning
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Lecture: TR9.30-11 (56-167)
______
Required introductory subject for graduate students pursuing environmental policy and planning as their specialization in the MCP Program. Also open to other graduate students interested in environmental policymaking and the practice of environmental planning. Taught comparatively, with numerous references to examples from around the world. Four major areas of focus: National Environmental Policymaking, Environmental Ethics, Environmental Forecasting and Analysis Techniques, and Strategies for Collaborative Decision-making.
L. Susskind
Textbooks (Fall 2016)

11.630[J] Environmental Law, Policy, and Economics: Pollution Prevention and Control
______

Graduate (Fall)
(Same subject as1.811[J],IDS.430[J])
(Subject meets with1.801[J],11.021[J],17.393[J])
Prereq: Permission of instructor for undergraduates
Units: 3-0-9
Credit cannot also be received for15.663
Lecture: TR3.30-5 (E51-057) +final
______
Reviews and analyzes federal and state regulation of air and water pollution, hazardous wastes, and the production and use of toxic chemicals. Analyzes pollution as an economic problem and the failure of markets. Emphasizes use of legal mechanisms and alternative approaches (such as economic incentives and voluntary approaches) to control pollution and to encourage chemical accident and pollution prevention. Focuses on the major federal legislation, the underlying administrative system, and the common law in analyzing environmental policy, economic consequences, and the role of the courts. Discusses classical pollutants and toxic industrial chemicals, community right-to-know, and environmental justice. Also provides an introduction to basic legal skills. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C. Caldart
Textbooks (Fall 2016)

11.631[J] Regulation of Chemicals, Radiation, and Biotechnology
______

Graduate (Spring)
Not offered regularly; consult department
(Same subject as1.812[J],IDS.431[J])
(Subject meets with1.802[J],10.805[J],11.022[J],IDS.436[J])
Prereq: 1.811 or permission of instructor
Units: 3-0-9
______
Focuses on policy design and evaluation in the regulation of hazardous substances and processes. Includes risk assessment, industrial chemicals, pesticides, food contaminants, pharmaceuticals, radiation and radioactive wastes, product safety, workplace hazards, indoor air pollution, biotechnology, victims' compensation, and administrative law. Health and economic consequences of regulation, as well as its potential to spur technological change, are discussed for each regulator regime. Students taking the graduate version are expected to explore the subject in greater depth.
N. Ashford, C.Caldart

11.701 Introduction to International Development Planning
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Lecture: TR9.30-11 (9-450B)
______
Studies interaction between planners and institutions at different scales, from local to global/transnational. Emphasizes a historical and institutional approaches to development planning. Includes an overview of theories of development, state, organizational arrangements, and implementation mechanisms. Covers current topics in development planning, such as decentralization, participatory planning, urban-rural linkages, corruption, legal institutions and post-conflict development. Analyzes various roles planners play in different institutional contexts. Restricted to first-year MCP and SPURS students.
B. Rajagopal
No textbook information available

Tutorials, Research, and Fieldwork Subjects

11.800 Reading, Writing and Research
______

Graduate (Spring)
Prereq: Permission of instructor,Coreq: 11.801
Units: 3-0-6 [P/D/F]
______
Required subject intended solely for 1st-year DUSP PhD students. Helps students prepare their first-year papers and plan for a dissertation. Focuses on how scholars get original ideas and write about them clearly and engagingly. Assignments ask students to apply generic readings and methods to individual first-year paper topics. Students work simultaneously with advisor on first-year paper, and present papers in the final weeks of the semester.
Staff

11.801 Doctoral Research Paper
______

Graduate (Spring)
Prereq: Permission of instructor,Coreq: 11.800
Units: 3-0-6
______
Students develop a first-year research paper in consultation with their advisor.
Staff

11.901 Independent Study: Urban Studies and Planning
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

11.902 Independent Study: Urban Studies and Planning
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Opportunity for independent study under regular supervision by a faculty member.
Staff
No required or recommended textbooks

11.903 Supervised Readings in Urban Studies
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

11.904 Supervised Readings in Urban Studies
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Reading and discussion of topics in urban studies and planning.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

11.905 Research Seminar in Urban Studies and Planning
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No required or recommended textbooks

11.906 Research Seminar in Urban Studies and Planning
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Special research issues in urban planning.
Staff
No required or recommended textbooks

11.907 Urban Fieldwork
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No required or recommended textbooks

11.908 Urban Fieldwork
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Practical application of planning techniques to towns, cities, and regions, including problems of replanning, redevelopment, and renewal of existing communities. Includes internships, under staff supervision, in municipal and state agencies and departments.
Staff
No required or recommended textbooks

11.909 Graduate Tutorial
______

Graduate (Fall) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Planned programs of instruction for a minimum of three students on a planning topic not covered in regular subjects of instruction. Registration subject to prior arrangement with appropriate faculty member.
Staff
No textbook information available

11.910 Doctoral Tutorial
______

Graduate (Fall)
Prereq: None
Units: 3-0-3 [P/D/F]
Selected dates. Lecture: R11-12.30 (9-450B)
______
Required subject exclusively for first-year DUSP PhD candidates, but with multiple colloquium sessions open to the full department community. Introduces students to a range of department faculty (and others) by offering opportunities to discuss applications of planning theory and planning history. Assists in clarifying the departments intellectual diversity. Encourages development of a personal intellectual voice and capacity to synthesize and respond to the arguments made by others.
L. Vale, J. Zhao
No required or recommended textbooks

11.920 Planning in Practice
(New)
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of Instructor
Units: 0-0-3 [P/D/F]
TBA.
______
Provides practical experience through internships secured by the student in the field of urban planning.
M. Daly
No textbook information available

11.960 Independent Study: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
No textbook information available

11.961 Independent Study: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Opportunity for independent study under regular supervision by a faculty member.
Staff
No textbook information available

11.962 Fieldwork: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Practical application of real estate techniques in the field.
Staff
No textbook information available

11.963 Independent Study: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No textbook information available

11.964 Independent Study: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Opportunity for independent study under regular supervision by a faculty member.
Staff
No textbook information available

11.985 Summer Field Work
______

Graduate (Summer)
Prereq: None
Units arranged [P/D/F]
______
Practical application of planning techniques over the summer with prior arrangement.
S. Wellford
No textbook information available

11.S938 Special Subject: Urban Studies and Planning
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
URL: http://dusp.mit.edu/subject/fall-2016-11s938
Lecture: TR2-3.30 (9-450B)
______
No textbook information available

11.S939 Special Subject: Urban Studies and Planning
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
No textbook information available

11.S940-11.S944 Special Subject: Urban Studies and Planning
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
11.S940: URL: http://dusp.mit.edu/subject/fall-2016-11s940
11.S941: URL: http://dusp.mit.edu/subject/fall-2016-11s941
11.S942: URL: http://dusp.mit.edu/subject/fall-2016-11s942
11.S943: URL: http://dusp.mit.edu/subject/fall-2014-11s943
11.S944: URL: http://dusp.mit.edu/subject/fall-2014-11s944
11.S940: Lecture: W EVE (4-6 PM) (10-401)
11.S941: Lecture: T EVE (4-6 PM) (9-450A)
11.S942: Lecture: W2-4 (9-217)
11.S943: TBA.
11.S944: TBA.
______
For graduate students wishing to pursue further study in advanced areas of urban studies and city and regional planning not covered in regular subjects of instruction.
M. Kothari
11.S940: No textbook information available
11.S941: No textbook information available
11.S942: No required or recommended textbooks
11.S943: No textbook information available
11.S944: No textbook information available

11.S945-11.S949 Special Subject: Urban Studies and Planning
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
11.S945: URL: http://dusp.mit.edu/subject/fall-2016-11s945
11.S946: URL: http://dusp.mit.edu/subject/spring-2016-11s946
11.S947: URL: http://dusp.mit.edu/subject/spring-2016-11s947
11.S948: URL: http://dusp.mit.edu/subject/spring-2016-11s948
11.S949: URL: http://dusp.mit.edu/subject/spring-2016-11s949
11.S945: Lecture: W EVE (2-6 PM) (9-255A)
______
For graduate students wishing to pursue further study in advanced areas of urban studies and city and regional planning not covered in regular subjects of instruction.
Staff
11.S945: No required or recommended textbooks

11.S950-11.S957 Special Seminar: Urban Studies and Planning
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
11.S950: URL: https://dusp.mit.edu/subject/fall-2016-11s950-0
11.S951: URL: http://dusp.mit.edu/subject/spring-2016-11s951
11.S952: URL: http://dusp.mit.edu/subject/spring-2016-11s952
11.S953: URL: http://dusp.mit.edu/subject/spring-2016-11s953
11.S955: URL: http://dusp.mit.edu/subject/fall-2014-11s955
11.S950: TBA.
11.S951: TBA.
11.S952: TBA.
11.S953: TBA.
Subject Cancelled 11.S955 Cancelled
Subject Cancelled 11.S956 Cancelled
11.S957: TBA.
______
For graduate students wishing to pursue further study in advanced areas of urban studies and city and regional planning not covered in regular subjects of instruction
Staff
11.S950: No textbook information available
11.S951: No textbook information available
11.S952: No textbook information available
11.S953: No textbook information available
11.S955: No textbook information available
11.S956: No textbook information available
11.S957: No textbook information available

11.S958 Special Seminar: Urban Studies and Planning
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______

11.S959 Special Seminar: Urban Studies and Planning
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
For graduate students wishing to pursue further study in advanced areas of urban studies and city and regional planning not covered in regular subjects of instruction.
Staff

11.S965 Special Subject: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No textbook information available

11.S966, 11.S967 Special Subject: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
11.S967: Begins Oct 17. Lecture: W10.30-12 (4-159)
______
11.S967: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

11.S968 Special Seminar: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
11.S968: TBA.
11.S969: TBA.
______
11.S968: No textbook information available
11.S969: No textbook information available

11.S969 Special Seminar: Real Estate
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit; first half of term
Prereq: Permission of instructor
Units arranged [P/D/F]
11.S968: TBA.
11.S969: TBA.
______
11.S968: No textbook information available
11.S969: No textbook information available

11.S970 Special Seminar: Real Estate
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
11.S968: TBA.
11.S969: TBA.
______
Small group study of advanced subjects under staff supervision. For graduate students wishing to pursue further study in advanced areas of real estate not covered in regular subjects of instruction.
Staff
11.S968: No textbook information available
11.S969: No textbook information available

11.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: M9.30-11 (9-255) Recitation: W9.30-11 (10-485, 9-451, 9-217)
______
Program of research and writing of thesis; to be arranged by the student with supervising committee.
Staff
Textbooks arranged individually


left arrow|Undergraduate: 11.00-11.199
plus UROP, ThU, ThT
|Graduate: 11.20-11.299|Graduate: 11.30-11.999 plus ThG|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 12: Earth, Atmospheric, and Planetary Sciences
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Course 12: Earth, Atmospheric, and Planetary Sciences
Fall 2016


Undergraduate Subjects

Core and General Science Subjects

12.000 Solving Complex Problems
______

Undergrad (Fall)
Prereq: None
Units: 1-2-6
Lecture: MWF3 (16-160)
______
Provides an opportunity for entering freshmen to gain firsthand experience in integrating the work of small teams to develop effective solutions to complex problems in Earth system science and engineering. Each year's class explores a different problem in detail through the study of complementary case histories and the development of creative solution strategies. Includes exercises in website development, written and oral communication, and team building. Subject required for students in the Terrascope freshman program, but participation in Terrascope is not required of all 12.000 students. Students who pass 12.000 are eligible to participate in the Terrascope field trip the following spring. Limited to freshmen.
D. McGee
No textbook information available

12.001 Introduction to Geology
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: None
Units: 3-4-5
Lecture: MWF1 (54-819) Lab: MWF2 (54-819)
______
Major minerals and rock types, rock-forming processes, and time scales. Temperatures, pressures, compositions, structure of the Earth, and measurement techniques. Geologic structures and relationships observable in the field. Sediment movement and landform development by moving water, wind, and ice. Crustal processes and planetary evolution in terms of global plate tectonics with an emphasis on ductile and brittle processes. Includes laboratory exercises on minerals, rocks, mapping, plate tectonics, rheology, glaciers. Two one-day field trips (optional).
EAPS Staff
Textbooks (Fall 2016)

12.002 Introduction to Geophysics and Planetary Science
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: Physics II (GIR), Calculus II (GIR)
Units: 3-1-8
______
Study of the structure, composition, and physical processes governing the terrestrial planets, including their formation and basic orbital properties. Topics include plate tectonics, earthquakes, seismic waves, rheology, impact cratering, gravity and magnetic fields, heat flux, thermal structure, mantle convection, deep interiors, planetary magnetism, and core dynamics. Suitable for majors and non-majors seeking general background in geophysics and planetary structure.
L. H. Royden, B. Weiss

12.003 Introduction to Atmosphere, Ocean, and Climate Dynamics
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR), Physics I (GIR)
Units: 3-1-8
URL: http://web.mit.edu/pog/www/12.003/Home.html
Lecture: MWF11 (54-1623) Recitation: TBA +final
______
Introduces the dynamical processes that govern the atmosphere, oceans, and climate. Topics include Earth's radiation budget, convection and clouds, the circulation of the atmosphere and ocean, and climate change. Illustrates underlying mechanisms through laboratory demonstrations with a rotating table, and through analysis of atmospheric and oceanic data.
P. O'Gorman
Textbooks (Fall 2016)

12.006[J] Nonlinear Dynamics: Chaos
______

Undergrad (Fall)
(Same subject as 2.050[J],18.353[J])
Prereq: 18.03 or 18.034; Physics II (GIR)
Units: 3-0-9
Lecture: TR1-2.30 (2-105)
______
Introduction to nonlinear dynamics and chaos in dissipative systems. Forced and parametric oscillators. Phase space. Periodic, quasiperiodic, and aperiodic flows. Sensitivity to initial conditions and strange attractors. Lorenz attractor. Period doubling, intermittency, and quasiperiodicity. Scaling and universality. Analysis of experimental data: Fourier transforms, Poincare sections, fractal dimension, and Lyapunov exponents. Applications to mechanical systems, fluid dynamics, physics, geophysics, and chemistry. See 12.207J/18.354J for Nonlinear Dynamics: Continuum Systems.
P-T. Brun
Textbooks (Fall 2016)

12.007 Geobiology: History of Life on Earth
______

Undergrad (Spring)
Prereq: None
Units: 3-0-9
______
Surveys the interactive Earth system: biology in geologic, environmental and climate change throughout Earth's history. Introduces the concept of "life as a geological agent" and examines the interaction between biology and the Earth system during the roughly 4 billion years since life first appeared. Topics include the origin of the solar system and the early Earth atmosphere; the origin and evolution of life and its influence on climate up through and including the modern age and the problem of global warming; the global carbon cycle; and astrobiology.
T. Bosak, G. Fournier

12.009[J] Nonlinear Dynamics: The Natural Environment
______

Undergrad (Spring)
(Same subject as18.352[J])
Prereq: Physics I (GIR), Calculus II (GIR);Coreq: 18.03
Units: 3-0-9
______
Analyzes cooperative processes that shape the natural environment, now and in the geologic past. Emphasizes the development of theoretical models that relate the physical and biological worlds, the comparison of theory to observational data, and associated mathematical methods. Topics include carbon cycle dynamics; ecosystem structure, stability and complexity; mass extinctions; biosphere-geosphere coevolution; and climate change. Employs techniques such as stability analysis; scaling; null model construction; time series and network analysis.
D. H. Rothman

12.010 Computational Methods of Scientific Programming
______

Undergrad (Fall)
Prereq: Calculus II (GIR), Physics I (GIR)
Units: 4-0-8
Lecture: TR2-4 (54-517)
______
Introduces programming languages and techniques used by physical scientists: FORTRAN, C, C++, MatLab, and Mathematica. Emphasis on program design, algorithm development and verification, and comparative advantages and disadvantages of different languages. Students first learn the basic usage of each language, common types of problems encountered, and techniques for solving a variety of problems encountered in contemporary research: examination of data with visualization techniques, numerical analysis, and methods of dissemination and verification. No prior programming experience is required.
T. Herring, C. Hill
No textbook information available

12.011[J] Archaeological Science
______

Undergrad (Spring) HASS Social Sciences
(Same subject as3.985[J],5.24[J])
Prereq: Chemistry (GIR) or Physics I (GIR)
Units: 3-1-5
______
Pressing issues in archaeology as an anthropological science. Stresses the natural science and engineering methods archaeologists use to address these issues. Reconstructing time, space, and human ecologies provides one focus; materials technologies that transform natural materials to material culture provide another. Topics include 14C dating, ice core and palynological analysis, GIS and other remote sensing techniques for site location, soil micromorphology and site formation, sourcing of metal artifacts, and microstructural and mechanical analyses of cementitious materials used in ancient monumental buildings.
H. N. Lechtman

12.012 MatLab, Statistics, Regression, Signal Processing
______

Undergrad (Fall)
(Subject meets with12.444)
Prereq: None.Coreq: 18.06
Units: 3-0-9
Lecture: TR11-12.30 (54-824)
______
Introduces the basic tools needed for data analysis and interpretation in the Geosciences, as well as other sciences. Composed of four modules, targeted at introducing students to the basic concepts and applications in each module. MatLab: Principles and practice in its uses, script and function modules, basic approaches to solving problems. Statistics: Correlation, means, dispersion, precision, accuracy, distributions, central limit theorem, skewness, probability, Chi-Square, Gaussian and other common distributions used in hypothesis testing. Regression: Random and grid search methods, basic least squares and algorithms applicable to regression, inversion and parameter estimation. Signal Processing: Analog and digital signals, Z-transform, Fourier series, fast Fourier transforms, spectral analysis leakage and bias, digital filtering. Students taking the graduate version complete different assignments.
F. D. Morgan, T. A. Herring, S. Ravela
No textbook information available

12.021 Earth Science, Energy, and the Environment
______

Undergrad (Fall)
Prereq: Physics I (GIR), Calculus I (GIR), Chemistry (GIR)
Units: 3-1-8
Lecture: MWF1 (8-119) +final
______
Provides understanding of the Earth System most relevant to production of our planet's natural energy resources, including the physics, chemistry, and biology of conventional and alternative energy sources. Includes a broad overview of traditional and alternative energy sources: hydrocarbons (conventional and unconventional), nuclear, geothermal, hydroelectric, and wind and tides, along with their potentials and limitations. Develops detailed knowledge of the formation, concentration, and production of fossil and nuclear fuels, as well as the waste products associated with their consumption. An examination of conventional and alternative energy sources includes the environmental issues associated with the exploitation of these resources, both regional and global.
B. H. Hager
No textbook information available

12.031A[J] Fundamentals of Ecology I
______

Undergrad (Fall); first half of term
(Same subject as1.018A[J],7.30A[J])
Prereq: None
Units: 2-0-4
Ends Oct 21. Lecture: TR11-12.30 (48-316) Recitation: M4 (48-316) or R4 (48-308)
______
Fundamentals of ecology, considering Earth as an integrated dynamic living system. Coevolution of the biosphere and geosphere, biogeochemical cycles, metabolic diversity, primary productivity, competition and the niche, trophic dynamics and food webs, population growth and limiting factors. Combination of 1.018A and 1.018B counts as REST subject.
O. Cordero, M. Follows
Textbooks (Fall 2016)

12.031B[J] Fundamentals of Ecology II
______

Undergrad (Fall); second half of term
(Same subject as1.018B[J],7.30B[J])
Prereq: 1.018A
Units: 2-0-4
Begins Oct 24. Lecture: TR11-12.30 (48-316) Recitation: M4 (48-316) or R4 (48-308) +final
______
Advanced topics in Ecology. Population modeling, global carbon cycle, climate change, geoengineering, theories of resource competition and mutualism, allometric scaling, ecological genomics, niche theory, human population growth. Applied ecology. Combination of 1.018A and 1.018B counts as REST subject.
O. Cordero, M. Follows
No required or recommended textbooks

12.086 Modeling Environmental Complexity
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with12.586)
Prereq: 18.03
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduction to mathematical and physical models of environmental processes. Emphasis on the development of macroscopic continuum or statistical descriptions of complex microscopic dynamics. Problems of interest include: random walks and statistical geometry of landscapes; percolation theory and transport in disordered media; fractals, scaling, and universality; ecological dynamics and the structure of ecosystems, food webs, and other natural networks; kinetics of biogeochemical cycles. Appropriate for advanced undergraduates. Beginning graduate students are encouraged to register for 12.586. Students taking the graduate version complete different assignments.
D. H. Rothman

12.090 Current Topics in Earth, Atmospheric, and Planetary Sciences
______

Undergrad (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No textbook information available

12.091 Current Topics in Earth, Atmospheric, and Planetary Sciences
______

Undergrad (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Laboratory or field work in earth, atmospheric, and planetary sciences. Consult with department Education Office.
EAPS Faculty

12.092 Current Topics in Geology and Geochemistry
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units arranged
______

12.093 Current Topics in Geology and Geochemistry
______

Undergrad (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Laboratory or field work in geology and geochemistry. To be arranged with department faculty. Consult with department Education Office.
EAPS Faculty

12.094 Current Topics in Geophysics
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

12.095 Current Topics in Geophysics
______

Not offered academic year 2016-2017Undergrad (IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Laboratory or field work in geophysics. To be arranged with department faculty. Consult with department Education Office.
EAPS Faculty

12.096 Current Topics in Atmospheric Science and Oceanography
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______

12.097 Current Topics in Atmospheric Science and Oceanography
______

Undergrad (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Laboratory or field work in atmospheric science and oceanography. To be arranged with department faculty. Consult with department Education Office.
EAPS Faculty

12.098 Current Topics in Planetary Science
______

Undergrad (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Laboratory or field work in planetary science. To be arranged with department faculty. Consult with department Education Office.
EAPS Staff

12.099 Current Topics in Planetary Science
______

Undergrad (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Laboratory or field work in planetary science. To be arranged with department faculty. Consult with department Education Office.
EAPS Faculty

Geology and Geochemistry

12.102 Environmental Earth Science
______

Undergrad (Fall) Rest Elec in Sci & Tech
Not offered regularly; consult department
Prereq: None
Units: 3-0-9
______
The geologic record demonstrates that our environment has changed over a variety of time scales from seconds to billions of years. Explores the many ways in which geologic processes control and modify the Earth's environment. Topics include chemical and physical interactions between the solid Earth, its oceans and atmosphere; the effect of catastrophic events such as volcanic eruptions and earthquakes on the environment; geologic hazards; and our role in modifying the environment through Earth resource development. Serves as an introduction to 12.120, which addresses field applications of these principles in the American Southwest.
S. A. Bowring

12.104 Geochemistry of the Earth and Planets
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: Calculus II (GIR)
Units: 3-2-7
Subject Cancelled Subject Cancelled
______
Focuses on low-temperature geochemistry and the Earth's biogeochemical cycles, including the biologic and inorganic chemical processes that create chemical variability and element partitioning among lithosphere, hydrosphere and atmosphere. Covers basic thermodynamics, aqueous chemistry, major and trace element geochemistry, and stable isotopic geochemistry.
S. Ono, D. McGee

12.108 Structure of Earth Materials
______

Undergrad (Fall)
Prereq: Chemistry (GIR)
Units: 3-4-5
Lecture: WF3-4.30 (54-819) Lab: WF9-11 (54-819) +final
______
Provides a comprehensive introduction to crystalline structure, crystal chemistry, and bonding in rock-forming minerals. Introduces the theory relating crystal structure and crystal symmetry to physical properties such as refractive index, elastic modulus, and seismic velocity. Surveys the distribution of silicate, oxide, and metallic minerals in the interiors and on the surfaces of planets, and discusses the processes that led to their formation.
T. L. Grove
Textbooks (Fall 2016)

12.109 Petrology
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 12.108
Units: 3-6-6
______
Surveys the distribution, chemical composition, and mineral associations in rocks of the Earth's crust and upper mantle, and establishes its relation to tectonic environment. Emphasis is on the use of chemistry and physics to interpret rock forming processes. Topics include dynamics of crust and mantle melting as preserved in the chemical composition of igneous rocks and minerals, the long-term record of global climate change as preserved in the minerals of sedimentary rocks, and the time-temperature-depth record preserved in minerals of metamorphosed crustal rocks.
T. L. Grove

12.110 Sedimentology and Stratigraphy
______

Not offered academic year 2017-2018Undergrad (Spring)
(Subject meets with12.465)
Prereq: 12.001
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Studies sediments in the rock cycle; production of sediments at the Earth's surface; physics and chemistry of sedimentary materials; scale and geometry of near-surface sedimentary bodies, including aquifers; sediment transport and deposition in modern sedimentary environments; and burial and lithification. Surveys major sedimentary rock types. Also covers stratigraphic relationships of sedimentary basins, and evolution of sedimentary processes through geologic time. Includes two or three weekend days of field trips. Students taking graduate version complete additional assignments.
K. Bergmann

12.113 Structural Geology
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 12.001
Units: 3-3-6
URL: http://web.mit.edu/12.113/www/
Subject Cancelled Subject Cancelled
______
Introduces mechanics of rock deformation. Discusses recognition, interpretation, and mechanics of faults, folds, structural features of igneous and metamorphic rocks, and superposed deformations. Introduces regional structural geology and tectonics. Laboratory includes techniques of structural analysis, recognition and interpretation of structures on geologic maps, and construction of interpretive cross sections.
O. Jagoutz

12.114 Field Geology I
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 12.108 or permission of instructor; orCoreq: 12.113
Units: 2-2-2 [P/D/F]
______
Introduces techniques of geological field study. Weather permitting, several weekend field exercises provide practical experience in preparation for 12.115. Presents introductory material on the regional geology of the locale of 12.115.
B. C. Burchfiel, O. Jagoutz

12.115 Field Geology II
______

Not offered academic year 2016-2017Undergrad (IAP) Institute Lab
Prereq: 12.113, 12.114
Units: 0-12-0
______
During January, students practice methods of modern geological field study off-campus during an intensive four-week experience. Exercises include geological and geomorphological mapping on topographic and photographic base maps of a wide variety of bedrock and surficial rocks. Where feasible, geochemical and geophysical field measurements are corrrelated with geology.
O. Jagoutz

12.116 Analysis of Geologic Data
______

Undergrad (Spring)
Prereq: 12.115
Units: 0-2-4
______
Includes in-depth laboratory analysis of samples, interpretation of geological data, and where possible, geophysical and geochemical data. Includes the preparation of reports based on the field studies conducted in 12.115 during January; report generally exceeds 30 pages in length and includes one major revision and rewrite. Instruction in writing techniques provided.
B. C. Burchfiel, O. Jagoutz

12.119 Analytical Techniques for Studying Environmental and Geologic Samples
______

Undergrad (Spring) Institute Lab
Prereq: None
Units: 2-6-4
______
Focuses on analytical facilities that are used to determine elemental and isotopic abundances in soils, rocks, minerals, and fluids. Emphasis is on isotopic ratios Sr, Nd, and Pb, whose isotopic ratios can be used for geochronology, and abundances of trace elements such as Rb, Sr, Cu, Cd, Hg, rare-earths, Pb, Th, and U. Analytical techniques include mass spectrometry, emission spectrometry, atomic absorption, neutron activation, and electron microprobe. A major lab project utilizes these techniques to address specific environmental and geologic problems.
E. Boyle, T. Grove

12.120 Environmental Earth Science Field Course
______

Not offered academic year 2016-2017Undergrad (IAP)
Prereq: Permission of instructor
Units: 1-5-0
______
Field study to foster understanding of natural hazards and human influence on the environment. Class conducted in the western United States, at locations such as Death Valley and the White Mountain Research Station in Bishop California. Topics include water use and availability, climate change, earthquakes and faulting, and landslides. Also examines volcanic hazards and geothermal power, effects of river diversion, and the geology of the Yucca Mountain facility for the storage of radioactive waste. Students partially responsible for travel expenses. Designed to follow 12.001 or 12.102; other students will be accepted when space is available.
T. L. Grove

12.141 Electron Microprobe Analysis
______

Undergrad (IAP)
Prereq: None
Units: 1-1-4 [P/D/F]
______
Introduction to the theory of x-ray microanalysis through the electron microprobe including ZAF matrix corrections. Techniques to be discussed are wavelength and energy dispersive spectrometry, scanning backscattered electron, secondary electron, cathodoluminescence, and x-ray imaging. Lab sessions involve use of the electron microprobe.
T. Grove, N. Chatterjee

12.158 Molecular Biogeochemistry
______

Not offered academic year 2017-2018Undergrad (Fall)
(Subject meets with12.458)
Prereq: Permission of instructor
Units: 2-4-3 [P/D/F]
Lecture: T4-5.30 (E25-605)
______
Covers all aspects of molecular biosignatures, such as their pathways of lipid biosynthesis, the distribution patterns of lipid biosynthetic pathways with regard to phylogeny and physiology, isotopic contents, occurrence in modern organisms and environments, diagenetic pathways, analytical techniques and the occurrence of molecular fossils through the geological record. Students analyze in depth the recent literature on chemical fossils. Lectures provide background on the subject matter. Basic knowledge of organic chemistry required. Students taking graduate version complete additional assignments.
R. Summons
No required or recommended textbooks

12.163 Geomorphology
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with12.463)
Prereq: 12.001, Physics I (GIR), Calculus I (GIR); or permission of instructor
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Quantitative examination of processes that shape Earth's surface. Introduction to fluvial, hillslope, and glacial mechanics. Essentials of weathering, soil formation, runoff, erosion, slope stability, sediment transport, and river morphology. Landscape evolution in response to climatic and tectonic forcing. Application of terrestrial theory to planetary surfaces. Additional instruction in geographic information systems (GIS) and remote sensing analysis, field measurement techniques, and numerical modeling of surface processes. Students taking the graduate version complete different assignments.
T. Perron

12.170 Essentials of Geology
______

Undergrad (Fall)
Not offered regularly; consult department
(Subject meets with12.470)
Prereq: Physics II (GIR), Calculus II (GIR); or permission of instructor
Units: 4-0-8
______
Studies the geology of planetary interiors and surfaces, including plate tectonics, as a unifying theory of terrestrial geology, surface processes, and the Earth's interior. Covers igneous, metamorphic, and sedimentary processes associated with tectonic settings and the typical rock suites created; mineral and rock identification; and causes of compositional differences on many scales (mineral grains, rocks, regions of the Earth, different planets). Also addresses conditions required for melting and melting processes; rock structure and field techniques; and Earth history. Treatment of these topics includes discussions of the geochemical, petrologic, geochronological, experimental, or field techniques used to investigate them; the limitations of current geological techniques and geological controversies; and major geological expeditions, experiments, and studies from the past, along with their premises and results. Students taking graduate version complete additional assignments.
EAPS Staff

Geophysics

12.201 Essentials of Global Geophysics
______

Not offered academic year 2017-2018Undergrad (Fall)
(Subject meets with12.501)
Prereq: Physics II (GIR), 18.03
Units: 4-0-8
URL: http://quake.mit.edu/~fjsimons/12.201-12.501.html
Lecture: MWF9 (54-824) +final
______
Overview of basic topics in solid-earth geophysics, such as the Earth's rotation, gravity and magnetic field, seismology, and thermal structure. Formulation of physical principles presented in three one-hour lectures per week. Current applications discussed in an additional one-hour tutorial each week. Students taking graduate version complete different assignments.
R. van der Hilst
No textbook information available

12.207[J] Nonlinear Dynamics: Continuum Systems
______

Undergrad (Spring)
(Same subject as1.062[J],18.354[J])
(Subject meets with18.3541)
Prereq: 18.03 or 18.034; Physics II (GIR)
Units: 3-0-9
______
General mathematical principles of continuum systems. From microscopic to macroscopic descriptions in the form of linear or nonlinear (partial) differential equations. Exact solutions, dimensional analysis, calculus of variations and singular perturbation methods. Stability, waves and pattern formation in continuum systems. Subject matter illustrated using natural fluid and solid systems found, for example, in geophysics and biology.
P. Pearce

12.213 Alternate Energy Sources
______

Undergrad (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units: 1-4-1 [P/D/F]
______
Explores a number of alternative energy sources such as geothermal energy (heat from the Earth's interior), wind, natural gas, and solar energy. Includes a field trip to visit sites where alternative energy is being harvested or generated. Content and focus of subject varies from year to year.
F. D. Morgan

12.214 Essentials of Applied Geophysics
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with12.507)
Prereq: 18.03
Units: 3-3-6
______
Introduces the application of geophysical methods to all aspects of near-surface environmental and engineering geophysics, including the exploration for petroleum, water, and minerals. Topics include seismic, electrical, electromagnetic, ground penetrating radar, magnetics, gravity, rock physics and chemistry, borehole geophysics and the global positioning system (GPS). Uses a quantitative approach to emphasize basic principles and a physical /chemical understanding of each method. Discusses specific illustrative field examples. Lab work is mainly devoted to local field work and equipment preparation for the IAP Field Geophysics class. Students taking graduate version complete additional assignments.
F. D. Morgan, T. A. Herring, B. H. Hager

12.221 Field Geophysics
______

Not offered academic year 2016-2017Undergrad (IAP)
(Subject meets with12.511)
Prereq: 12.214
Units: 1-4-1 [P/D/F]
______
Covers practical methods of modern geophysics, including the global positioning system (GPS), gravity, and magnetics. Field work is conducted in western US and includes intensive 10-day field exercise. Focuses on measurement techniques and their interpretation. Introduces the science of gravity, magnetics, and the GPS. Measures crustal structure, fault motions, tectonic deformations, and the local gravity and magnetic fields. Students perform high-precision measurements and participate in data analysis. Emphasizes principles of geophysical data collection and the relevance of these data for tectonic faulting, crustal structure, and the dynamics of the earthquake cycle. Students taking graduate version complete additional assignments.
T. A. Herring, B. H. Hager, F. D. Morgan

12.222 Field Geophysics Analysis
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with12.512)
Prereq: 12.221
Units: 2-0-4
______
Focuses on in-depth data analysis and development of skills needed to report results both in writing and orally. Students use data collected in 12.221 to develop written and oral reports of the results, with each student focusing on a different area. For example, students can develop the geophysical modeling or synthesis of the results into other studies in the area. The final written and oral reports are combined into a comprehensive report and presentation of the field camp and its results. Students taking graduate version complete additional assignments.
T. A. Herring, B. H. Hager, F. D. Morgan

Atmospheres, Oceans, and Climate

12.300[J] Global Change Science
______

Not offered academic year 2016-2017Undergrad (Fall)
(Same subject as1.071[J])
Prereq: 18.03
Units: 3-0-9
______
Introduces the basic relevant principles and concepts in atmospheric physics, climate dynamics, biogeochemistry, and water and energy balance at the land-atmosphere boundary, through an examination of two current problems in the global environment: carbon dioxide and global warming; and tropical deforestation and regional climate. An introduction to global environmental problems for students in basic sciences and engineering.
E. A. B. Eltahir

12.301 Climate Science
______

Undergrad (Fall)
(Subject meets with12.842)
Prereq: Chemistry (GIR), 18.03, or permission of instructor
Units: 4-0-8
Lecture: MWF2 (54-824)
______
Introduction to climate studies, including beginnings of the solar system, time scales, and climate in human history; methods for detecting climate change, including proxies, ice cores, instrumental records, and time series analysis; physical and chemical processes in climate, including primordial atmosphere, ozone chemistry, carbon and oxygen cycles, and heat and water budgets; internal feedback mechanisms, including ice, aerosols, water vapor, clouds, and ocean circulation; climate forcing, including orbital variations, volcanism, plate tectonics, and solar variability; climate models and mechanisms of variability, including energy balance, coupled models, and global ocean and atmosphere models; and outstanding problems. Students taking the graduate version complete different assignments.
K. Emanuel, E. Boyle, D. McGee
Textbooks (Fall 2016)

12.306 Atmospheric Physics and Chemistry
______

Undergrad (Spring)
(Subject meets with10.571[J],12.806[J])
Prereq: 5.60 or 5.61; 18.075; or permission of instructor
Units: 3-0-9
______
Introduction to the physics and chemistry of the atmosphere including experience with computer codes. Aerosols and theories of their formation, evolution, and removal. Gas and aerosol transport from urban to continental scales. Coupled models of radiation, transport, and chemistry. Solution of inverse problems to deduce emissions and removal rates. Emissions control technology and costs. Applications to air pollution and climate. Students taking the graduate version complete different assignments.
R. G. Prinn

12.307 Weather and Climate Laboratory
______

Undergrad (Spring) Institute Lab
Prereq: Calculus II (GIR), Physics I (GIR)
Units: 1-4-10
URL: http://paoc.mit.edu/12307/
______
A laboratory subject intended to illustrate, by means of hands-on projects, the basic dynamical and physical principles which govern the general circulation of the atmosphere and the day-to-day sequence of weather events. Real-time meteorological observations are studied together with laboratory fluid experiments. Projects based on real-time observations stress the analysis and dynamical interpretation of the real phenomena, while complementary rotating tank experiments stress planning and testing of ideas in a more controlled laboratory environment. Written critical summaries of the results of each project and oral presentations are an integral part of the subject.
L. Illari, J. Marshall

12.310 An Introduction to Weather Forecasting
______

Undergrad (IAP)
Prereq: Physics I (GIR), Calculus I (GIR)
Units: 1-1-4 [P/D/F]
URL: http://paoc.mit.edu/synoptic/courses/12.310/12310.htm
______
Basic principles of synoptic meteorology and weather forecasting. Analysis of hourly weather data and numerical weather prediction models. Regular preparation of weather forecasts.
L. Illari

12.320A[J] Introduction to Hydrology and Water Resources
______

Undergrad (Fall); first half of term
(Same subject as1.070A[J])
Prereq: 1.060A;Coreq: 1.061A, 1.106
Units: 2-0-4
Ends Oct 21. Lecture: TR9.30-11 (48-316) Recitation: M1 (48-308)
______
Water in the environment; Water resource systems; The hydrologic cycle at its role in the climate system; Surface water and energy balance; evaporation and transpiration through vegetation; Precipitation formation, infiltration, storm runoff, and flood processes; Groundwater aquifers, subsurface flow and the hydraulics of wells.
D. Entekhabi
No textbook information available

12.320B[J] Introduction to Hydrology Modeling
______

Undergrad (Fall); second half of term
(Same subject as1.070B[J])
Prereq: 1.070A
Units: 2-0-4
Begins Oct 24. Lecture: TR9.30-11 (48-316) Recitation: M1 (48-308)
______
Develops understanding of numerical modeling of aquifers, groundwater flow and contaminant transport, as well as uncertainty and risk analysis for water resources.
D. Entekhabi
No textbook information available

12.330[J] Fluid Physics
______

Undergrad (Spring)
(Same subject as8.292[J])
Prereq: 8.044, 5.60, or permission of instructor
Units: 3-0-9
______
A physics-based introduction to the properties of fluids and fluid systems, with examples drawn from a broad range of sciences, including atmospheric physics and astrophysics. Definitions of fluids and the notion of continuum. Equations of state and continuity, hydrostatics and conservation of momentum; ideal fluids and Euler's equation; viscosity and the Navier-Stokes equation. Energy considerations, fluid thermodynamics, and isentropic flow. Compressible versus incompressible and rotational versus irrotational flow; Bernoulli's theorem; steady flow, streamlines and potential flow. Circulation and vorticity. Kelvin's theorem. Boundary layers. Fluid waves and instabilities. Quantum fluids.
D. Cziczo

12.333 Atmospheric Dynamics
______

Undergrad (Fall)
Not offered regularly; consult department
Prereq: 12.003, 8.03, 18.03; or permission of instructor
Units: 4-0-8
______
Discusses the dynamics of the atmosphere, with emphasis on the large scale. Topics include zonally symmetric circulations and the tropical Hadley circulation; internal gravity waves; balanced flows, potential vorticity conservation and Rossby waves; stability of zonal flows; baroclinic instability and extratropical storms; tropical waves, the Walker circulation, and El Niño and the Southern Oscillation; and the role of eddies in the general circulation. Students taking graduate version complete different assignments.
EAPS Staff

12.335 Experimental Atmospheric Chemistry
______

Undergrad (Fall) Institute Lab
(Subject meets with12.835)
Prereq: Chemistry (GIR)
Units: 2-4-6
Lecture: TR1.30-3 (54-1623)
______
Introduces the atmospheric chemistry involved in climate change, air pollution, and ozone depletion using a combination of interactive laboratory and field studies and simple computer models. Uses instruments for trace gas and aerosol measurements and methods for inferring fundamental information from these measurements. Provides instruction and practice in written and oral communication. Students taking the graduate version complete different assignments.
R. Prinn, S. Ono, K. Dryer
No required or recommended textbooks

12.336[J] Air Pollution
______

Undergrad (Fall)
(Same subject as1.085[J])
Prereq: 18.03
Units: 3-0-9
Lecture: MW10.30-12 (48-308)
______
Provides a working knowledge of basic air quality issues, with emphasis on a multidisciplinary approach to investigating the sources and effects of pollution. Topics include emission sources; atmospheric chemistry and removal processes; meteorological phenomena and their impact on pollution transport at local to global scales; air pollution control technologies; health effects; and regulatory standards. Discusses regional and global issues, such as acid rain, ozone depletion and air quality connections to climate change.
C. Heald
Textbooks (Fall 2016)

12.338 Aerosol and Cloud Microphysics and Chemistry
______

Undergrad (Spring)
(Subject meets with1.842[J],12.814[J])
Prereq: 12.335, 12.336 or permission of instructor
Units: 3-0-9
______
Focuses on understanding how aerosol particles form droplets or ice crystals during several atmospheric processes: determining Earth's radiative balance; heterogeneous chemistry and acid rain; understanding where, when and how much precipitation occurs. Provides tools for understanding the physics of aerosol and cloud element motion; the interaction of particles with water vapor, including phase changes and droplet and ice nucleation; the chemical composition of particles and the effect on cloud formation processes; and the effect of cloud processing on aerosol chemistry. Discusses relevant topics of contemporary interest, e.g., geoengineering and weather modification and volcanic effects. Students taking the graduate version complete different assignments.
D. Cziczo

12.340 Global Warming Science
______

Undergrad (Spring)
Prereq: Calculus I (GIR), Physics I (GIR), or permission of instructor;Coreq: 5.60
Units: 3-0-9
______
Provides students with a scientific foundation of anthropogenic climate change and an introduction to climate models. Focuses on fundamental physical processes that shape climate (e.g. solar variability, orbital mechanics, greenhouse gases, atmospheric and oceanic circulation, and volcanic and soil aerosols) and on evidence for past and present climate change. Discusses material consequences of climate change, including sea level change, variations in precipitation, vegetation, storminess, and the incidence of disease. Examines the science behind mitigation and adaptation proposals.
EAPS Staff

12.346[J] Global Environmental Negotiations
______

Undergrad (Fall)
(Same subject asIDS.062[J])
(Subject meets with12.846[J],IDS.525[J])
Prereq: Permission of instructor
Units: 2-0-4
Lecture: T2.30-4.30 (4-144)
______
Practical introduction to global environmental negotiations designed for science and engineering students. Covers basic issues in international negotiations, such as North-South conflict, implementation and compliance, trade, and historical perspective on global environmental treaties. Offers hands-on practice in developing and interpreting international agreements through role-play simulations and observation of ongoing climate change negotiating processes. Students taking graduate version complete additional assignments.
N. E. Selin
Textbooks (Fall 2016)

12.348[J] Global Climate Change: Economics, Science, and Policy
______

Undergrad (Spring)
(Same subject as15.026[J])
(Subject meets with12.848[J],15.023[J])
Prereq: Calculus II (GIR); 5.60; 14.01 or 15.010; or permission of instructor
Units: 3-0-6
______
Introduces scientific, economic, and ecological issues underlying the threat of global climate change, and the institutions engaged in negotiating an international response. Develops an integrated approach to analysis of climate change processes, and assessment of proposed policy measures, drawing on research and model development within the MIT Joint Program on the Science and Policy of Global Change. Graduate students are expected to explore the topic in greater depth through reading and individual research. 12.340 recommended.
R. G. Prinn

12.349 Mechanisms and Models of the Global Carbon Cycle
______

Undergrad (Spring)
(Subject meets with12.849)
Prereq: Calculus II (GIR), Physics I (GIR)
Units: 3-0-9
______
Addresses changes in the ocean, terrestrial biosphere and rocks modulation of atmospheric carbon dioxide on timescales from months to millions of years. Includes feedbacks between carbon cycle and climate. Combines hands-on data analysis with the formulation of simple models rooted in basic physical, chemical and biological principles. Students create individual "toy" global carbon cycle models. Students taking graduate version complete different assignments.
M. Follows

12.385 Science, Politics, and Environmental Policy
______

Undergrad (Fall)
(Subject meets with11.373[J],12.885[J])
Prereq: Permission of instructor
Units: 3-0-6
Lecture: M EVE (3-6 PM) (54-1623)
______
Examines the role of science in US and international environmental policymaking. Surveys the methods by which scientists learn about the natural world; the treatment of science by experts, advocates, the media, and the public and the way science is used in legislative, administrative and judicial decision making. Through lectures, group discussions, and written essays, students develop a critical understanding of the role of science in environmental policy. Potential case studies include fisheries management, ozone depletion, global warming, smog, and endangered species. Students taking the graduate version complete different assignments.
S. Solomon, J. Knox-Hayes
No required or recommended textbooks

Planetary Science and Astronomy

12.400 The Solar System
______

Undergrad (Spring) Rest Elec in Sci & Tech
Not offered regularly; consult department
Prereq: Physics I (GIR)
Units: 3-0-9
______
Introduction to the study of the solar system with emphasis on the latest spacecraft results. Subject covers basic principles rather than detailed mathematical and physical models. Topics include an overview of the solar system, planetary orbits, rings, planetary formation, meteorites, asteroids, comets, planetary surfaces and cratering, planetary interiors, planetary atmospheres, and life in the solar system.
R. P. Binzel

12.402[J] Introduction to Astronomy
______

Undergrad (Spring) Rest Elec in Sci & Tech
(Same subject as8.282[J])
Prereq: Physics I (GIR)
Units: 3-0-6
______
Quantitative introduction to physics of the solar system, stars, interstellar medium, the galaxy, and universe, as determined from a variety of astronomical observations and models. Topics: planets, planet formation; stars, the Sun, "normal" stars, star formation; stellar evolution, supernovae, compact objects (white dwarfs, neutron stars, and black holes), plusars, binary x-ray sources; star clusters, globular and open clusters; interstellar medium, gas, dust, magnetic fields, cosmic rays; distance ladder; galaxies, normal and active galaxies, jets; gravitational lensing; large scaling structure; Newtonian cosmology, dynamical expansion and thermal history of the universe; cosmic microwave background radiation; big bang nucleosynthesis. No prior knowledge of astronomy necessary. Not usable as a restricted elective by Physics majors.
Staff

12.409 Hands-On Astronomy: Observing Stars and Planets
______

Undergrad (Spring)
Prereq: None
Units: 0-4-2 [P/D/F]
______
Background for, and techniques of, visual observation and electronic imaging of the Moon, planets, satellites, stars, and brighter deep-space objects. Weekly outdoor observing sessions using 8-inch diameter telescopes when weather permits. Indoor sessions introduce skills necessary for observation. Introduction to contemporary observational astronomy including astronomical computing, image and data processing, and how astronomers work. Student must maintain a careful and complete written log which is graded. Consumes an entire evening each week; 100% attendance at observing sessions required to pass. Enrollment limited; priority to freshmen.
A. Bosh

12.410[J] Observational Techniques of Optical Astronomy
______

Undergrad (Fall) Institute Lab
(Same subject as8.287[J])
Prereq: 8.282J, 12.402J, 12.409, or other introductory astronomy course;Coreq: 8.03
Units: 3-4-8
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: MWF1 (54-517) Lab: TBA
______
Fundamental physical and optical principles used for astronomical measurements at visible wavelengths and practical methods of astronomical observations. Topics: astronomical coordinates, time, optics, telescopes, photon counting, signal-to-noise ratios, data analysis (including least-squares model fitting), limitations imposed by the Earth's atmosphere on optical observations, CCD detectors, photometry, spectroscopy, astrometry, and time variability. Project at Wallace Astrophysical Observatory. Written and oral project reports. Limited to 18; preference to Course 8 and Course 12 majors and minors.
R. Binzel, A. Bosh
Textbooks (Fall 2016)

12.411 Astronomy Field Camp
______

Undergrad (IAP) Can be repeated for credit
Prereq: 12.410 or 8.287
Units: 0-6-3 [P/D/F]
______
Individual research projects in planetary science and astrophysics, involving supervised work at Lowell Observatory in Flagstaff, AZ. Projects may include observations made using Lowell's telescope facilities. Project topics and objectives vary from year to year. Written and oral reports required. Limited to 6.
A. Bosh

12.420 Physics and Chemistry of the Solar System
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with12.601)
Prereq: 12.002 or permission of instructor
Units: 3-0-9
______
Advanced applications of physical and chemical principles to the study of the solar system. Topics include terrestrial and giant planets, meteorites, asteroids, comets, Kuiper belt objects, rings, impact craters, interiors, surfaces, atmospheres, geomagnetism, cosmochemistry, remote sensing, formation and evolution of the solar system.
B. P. Weiss

12.425[J] Extrasolar Planets: Physics and Detection Techniques
______

Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject as8.290[J])
(Subject meets with12.625)
Prereq: 8.03, 18.03
Units: 2-1-9
Lecture: TR1.30-3 (54-824)
______
Presents basic principles of planet atmospheres and interiors applied to the study of extrasolar planets. Focuses on fundamental physical processes related to observable extrasolar planet properties. Provides a quantitative overview of detection techniques. Introduction to the feasibility of the search for Earth-like planets, biosignatures and habitable conditions on extrasolar planets. Students taking graduate version complete additional assignments.
S. Seager
No textbook information available

12.43[J] Space Systems Engineering
______

Undergrad (Spring)
(Same subject as16.83[J])
Prereq: Permission of instructor
Units: 3-3-6
______
Design of a complete space system, including systems analysis, trajectory analysis, entry dynamics, propulsion and power systems, structural design, avionics, thermal and environmental control, human factors, support systems, and weight and cost estimates. Students participate in teams, each responsible for an integrated vehicle design, providing experience in project organization and interaction between disciplines. Includes several aspects of team communication including three formal presentations, informal progress reports, colleague assessments, and written reports. Course 16 students are expected to complete two professional or concentration subjects from the departmental program before taking this capstone. Offered alternate fall and spring terms.
J. A. Hoffman, A. Saenz-Otero

12.431[J] Space Systems Development
______

Not offered academic year 2016-2017Undergrad (Spring) Institute Lab
(Same subject as16.831[J])
Prereq: Permission of instructor
Units: 2-10-6
______
Students build a space system, focusing on refinement of sub-system designs and fabrication of full-scale prototypes. Sub-systems are integrated into a vehicle and tested. Sub-system performance is verified using methods of experimental inquiry, and is compared with physical models of performance and design goals. Communication skills are honed through written and oral reports. Formal reviews include the Implementation Plan Review and the Acceptance Review. Knowledge of the engineering design process is helpful.
J. A. Hoffman, A. Saenz-Otero

Independent Research Subjects

12.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

12.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Undergraduate research opportunities in Earth, Atmospheric, and Planetary Sciences.
Consult Department UROP Coordinator
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

12.IND Independent Study
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: 12.TIP
Units arranged
______
Independent reading, laboratory, or fieldwork in Earth, Atmospheric, and Planetary Sciences. To be arranged by student and an appropriate EAPS faculty member. A written report may be required at the discretion of the advisor. Units arranged should reflect the project requirements.
Consult EAPS Education Office

12.TIP Thesis Preparation
______

Undergrad (Fall, Spring)
Prereq: None
Units: 2-0-4
TBA.
______
Definition of and early-stage work on the thesis project. Students develop a written research proposal and begin writing the supporting text of the thesis concurrent with conducting research for the thesis project. Supervision of the writing continues into the spring term which concludes with an oral presentation of the research results.
J. Connor
No required or recommended textbooks

12.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 12.TIP
Units arranged
TBA.
______
Program of research leading to the writing of a thesis; to be arranged by the student and an appropriate MIT faculty member.
EAPS Faculty
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|12.00-12.439 plus UROP, IND, TIP, ThU|12.440-12.599 plus ThG|12.600-12.999|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 12: Earth, Atmospheric, and Planetary Sciences
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Course 12: Earth, Atmospheric, and Planetary Sciences
Fall 2016


Graduate Subjects

12.440, 12.441 Collaborative Seminar in Geology and Geophysics
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Focuses on problems of current interest in geology and geophysics; subject matter varies from term to term. Includes guest speakers from outside of EAPS. 12.441 is graded P/D/F.
Geology and Geophysics Staff

12.442, 12.443 Collaborative Seminar in Planetary Science
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Focuses on problems of current interest in planetary science; subject matter varies from term to term. Includes guest speakers from outside of EAPS. 12.443 is graded P/D/F.
Planetary Science Staff

12.444 MatLab, Statistics, Regression, Signal Processing
______

Graduate (Fall)
(Subject meets with12.012)
Prereq: 18.06
Units: 3-0-9
Lecture: TR11-12.30 (54-824)
______
Introduces the basic tools needed for data analysis and interpretation in the Geosciences, as well as other sciences. Composed of four modules, targeted at introducing students to the basic concepts and applications in each module. MatLab: Principles and practice in its uses, script and function modules, basic approaches to solving problems. Statistics: Correlation, means, dispersion, precision, accuracy, distributions, central limit theorem, skewness, probability, Chi-Square, Gaussian and other common distributions used in hypothesis testing. Regression: Random and grid search methods, basic least squares and algorithms applicable to regression, inversion and parameter estimation. Signal Processing: Analog and digital signals, Z-transform, Fourier series, fast Fourier transforms, spectral analysis leakage and bias, digital filtering. Students taking the graduate version complete different assignments.
F. D. Morgan, T. A. Herring, S. Ravela
No textbook information available

12.445 Communication in the Earth, Atmospheric, and Planetary Sciences
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-3 [P/D/F]
Subject Cancelled Subject Cancelled
______
Concentrated instruction and practice in professional writing and presentation. Topics include review of various communication styles prevalent in the field; strategies for tailoring reports, technical papers, and presentations for specific audiences; and mechanics of organization and style. Weekly assignments in writing or speaking, with peer and instructor feedback. Limited to 6.
F. D. Morgan

12.446 Teaching Experience in EAPS
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Recognizes the educational value derived from satisfactory performance of assigned duties as a Teaching Assistant. Laboratory, field, recitation, or classroom teaching under supervision of a faculty member. Credit for this subject may not be used for any degree granted by Course 12. Total enrollment limited by availability of suitable teaching assignments.
EAPS Staff
No required or recommended textbooks

12.447 Strategies for Writing Successful Fellowship Proposals
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-0 [P/D/F]
______
Focuses on developing writing skills appropriate for preparing successful fellowship proposals. Includes writing practice, self-evaluation, and faculty feedback.
Staff

12.448, 12.449 Collaborative Seminar in Atmospheres, Oceans and Climate
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Focuses on problems of current interest in atmospheres, oceans, and climate; subject matter varies from term to term. Includes guest speakers from outside of EAPS. 12.449 is graded P/D/F.
PAOC Staff

12.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of an SM, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member.
Consult Department Headquarters
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

Geology and Geochemistry

12.450 Seminar in Geology and Geochemistry
______

Graduate (Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
______
Seminar on topics of current interest in geology and geochemistry. Required background preparation for students taking pre-doctoral general examinations in these subjects.
Geology and Geochemistry Staff

12.451 Seminar in Regional Tectonics
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-6 [P/D/F]
______
Applies techniques of tectonic synthesis to study the roles of particular orogenic belts in global plate tectonics. Treats different applications in different terms, so that the subject may be taken repeatedly to learn the range of orogenic responses to temporal and spatial variations of activity at plate boundaries.
B. C. Burchfiel, L. H. Royden

12.453-12.454 Crosby Lectures in Geology
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-6 [P/D/F]
______
A series of presentations on an advanced topic in the field of geology by the visiting William Otis Crosby lecturer. The Crosby lectureship is awarded to a distinguished international scientist each year to introduce new scientific perspectives to the MIT community. Subject content and structure vary from year to year.
Consult Department Education Office

12.456 Seminar in Rock Mechanics
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
______
Discussion of current research or advanced topics in continental tectonics, rock mechanics, or experimental structural geology.
B. Evans

12.458 Molecular Biogeochemistry
______

Not offered academic year 2017-2018Graduate (Fall)
(Subject meets with12.158)
Prereq: Permission of instructor
Units: 2-4-3 [P/D/F]
Lecture: T4-5.30 (E25-605)
______
Covers all aspects of molecular biosignatures, such as their pathways of lipid biosynthesis, the distribution patterns of lipid biosynthetic pathways with regard to phylogeny and physiology, isotopic contents, occurrence in modern organisms and environments, diagenetic pathways, analytical techniques and the occurrence of molecular fossils through the geological record. Students analyze in depth the recent literature on chemical fossils. Lectures provide background on the subject matter. Basic knowledge of organic chemistry required. Students taking graduate version complete additional assignments.
R. Summons
No required or recommended textbooks

12.460-12.461 Current Research in Geology and Geochemistry
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.460: TBA.
12.461: TBA.
______
Original investigations on problems in geology, petrology, mineralogy, geochemistry, or geobiology. 12.460 is letter-graded.
EAPS Staff
12.460: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.461: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.463 Geomorphology
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with12.163)
Prereq: 12.001, Physics I (GIR), Calculus I (GIR); or permission of instructor
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Quantitative examination of processes that shape Earth's surface. Introduction to fluvial, hillslope, and glacial mechanics. Essentials of weathering, soil formation, runoff, erosion, slope stability, sediment transport, and river morphology. Landscape evolution in response to climatic and tectonic forcing. Application of terrestrial theory to planetary surfaces. Additional instruction in geographic information systems (GIS) and remote sensing analysis, field measurement techniques, and numerical modeling of surface processes. Students taking the graduate version complete different assignments.
T. Perron

12.465 Sedimentology and Stratigraphy
______

Not offered academic year 2017-2018Graduate (Spring)
(Subject meets with12.110)
Prereq: Permission of instructor
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Studies sediments in the rock cycle; production of sediments at the Earth's surface; physics and chemistry of sedimentary materials; scale and geometry of near-surface sedimentary bodies, including aquifers; sediment transport and deposition in modern sedimentary environments; and burial and lithification. Surveys major sedimentary rock types. Also covers stratigraphic relationships of sedimentary basins, and evolution of sedimentary processes through geologic time. Includes two or three weekend days of field trips. Students taking graduate version complete additional assignments.
K. Bergmann

12.467 Seminar in Geomorphology
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
______
Discussion of current research or advanced topics in landscape evolution, surface hydrology, mechanics of sediment transport, basin analysis, or experimental geomorphology. Advanced instruction in process geomorphology.
EAPS Staff

12.470 Essentials of Geology
______

Graduate (Fall)
Not offered regularly; consult department
(Subject meets with12.170)
Prereq: Physics II (GIR), Calculus II (GIR); or permission of instructor
Units: 4-0-8
______
Geology of planetary interiors and surfaces, including plate tectonics, as a unifying theory of terrestrial geology, surface processes, and the Earth's interior. Igneous, metamorphic, and sedimentary processes associated with tectonic settings and the typical rock suites created. Mineral and rock identification. Causes of compositional differences on many scales: mineral grains, rocks, regions of the Earth, different planets. Conditions required for melting and melting processes. Rock structure and field techniques. Earth history. Treatment of these topics includes discussions of the geochemical, petrologic, geochronological, experimental, or field techniques used to investigate them; the limitations of current geological techniques and geological controversies; and great geological expeditions, experiments, and studies from the past, their premises, and their results. Students taking graduate version complete additional assignments.
EAPS Staff

12.471 Essentials of Geobiology
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: None
Units: 3-4-5
Lecture: MW9.30-11 (E25-605)
______
Introduces basic concepts of microbial structure, growth, energetics, molecular biology, and biochemistry. Presents examples of microbial interactions with environments throughout Earth's history as well as current topics in astrobiology. Includes lectures, discussions of literature, and a field trip. Lab focuses on student-designed projects that involve cultivation, modeling, or sample analyses. Intended for students whose background is not in biology, but who want to learn more about the contribution of microbes to geochemistry and planetary evolution.
T. Bosak
No textbook information available

12.473 Paleomagnetism and Planetary Magnetism
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 12.002, 18.03; or permission of instructor
Units: 2-0-4
Subject Cancelled Subject Cancelled
______
Introduces the study of natural remanent magnetization and the generation of planetary magnetic fields. Topics include paleomagnetism, rock magnetism, geomagnetism, magnetostratigraphy, paleomagnetic measurement techniques, polar wander and continental drift, biomagnetism, dynamo theory, and the history and evolution of magnetic fields on the Earth and planets.
B. P. Weiss

12.474 Origin and Evolution of the Earth's Crust
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
______
Broad overview of the origin and evolution of Earth's crust and mantle with emphasis on the study of the Precambrian rock record. Topics include: processes of crustal growth, stabilization, and reactivation; evaluation of secular change; and use of radiogenic isotopes in geochronology and as tracers of crust forming processes.
O. Jagoutz

12.475 Plate Tectonics and Continental Deformation
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
______
First half covers basic elements of plate tectonics, including sea floor spreading, magnetic anomalies, and subduction zone. Second half covers implications of plate tectonics for continental processes, including continental rifting, continental collision, and mountain building. Emphasis will be on correlating plate tectonic and continental processes using specific examples from around the world.
L. H. Royden

12.476 Radiogenic Isotope Geology
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-3-6
______
Applications of the variations in the relative abundance of radiogenic isotopes to problems of petrology, geochemistry, and tectonics. Topics: geochronology; isotopic evolution of Earth's crust and mantle; petrogenesis; and analytical techniques.
S. Bowring

12.480 Thermodynamics for Geoscientists
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 5.60 or 3.046
Units: 3-3-6
Subject Cancelled Subject Cancelled
______
Principles of thermodynamics are used to infer the physical conditions of formation and modification of igneous and metamorphic rocks. Includes phase equilibria of homogeneous and heterogeneous systems and thermodynamic modelling of non-ideal crystalline solutions. Surveys the processes that lead to the formation of metamorphic and igneous rocks in the major tectonic environments in the Earth's crust and mantle.
T. L. Grove

12.481 Advanced Field Geology I
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: 12.113, 12.114
Units: 2-2-2 [P/D/F]
Subject Cancelled Subject Cancelled
______
Introduction to the problems to be investigated in 12.482, as well as the regional setting and local geology of the field area. Various special techniques may be introduced and preparatory investigations may be conducted that are specific to the area to be studied in 12.482.
B. C. Burchfiel, O. Jagoutz

12.482 Advanced Field Geology II
______

Not offered academic year 2016-2017Graduate (IAP, Spring) Can be repeated for credit
Prereq: 12.481
Units arranged
______
In January, a geological and geomorphological study of a selected field area is conducted during a four-week excursion. The following term includes: preparation of maps and report based on field study conducted in January; and laboratory analysis of samples.
B. C. Burchfiel

12.484 Directed Field Studies
______

Graduate (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 0-6-0
______
Intensive training in field geological methods. Includes specific exercises selected to complement the backgrounds of the students enrolled and provides supervised experience in applying field analytical techniques to geological problems. Cannot be taken as a substitute for 12.115. Preference will be given to students associated with Course 12. Enrollment limited; students should apply early.
B. C. Burchfiel

12.485 Advanced Directed Field Studies
______

Graduate (IAP) Can be repeated for credit
Not offered regularly; consult department
Prereq: 12.484
Units: 0-6-0
______
Continuation of 12.484. Designed to provide more advanced training in specific field geological methods. Can be taken during the same IAP period as 12.484. Preference will be given to students associated with Course 12. Enrollment limited; students should apply early.
Staff

12.486 Advanced Igneous Petrology
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-2-7
______
Comprehensive overview of igneous rocks from the Earth, Moon, and meteorite parent bodies. Discusses the compositional diversity of igneous rocks and how it can be used to elucidate rock forming processes in the major tectonic provinces on modern Earth, including mid-ocean ridges, subduction zones, ocean islands, and inter-continental rifting environments. Also covers magma generation processes in the terrestrial planets prior to 2.6 billion years ago. Laboratory exercises on selected suites of igneous rocks reinforce readings and classroom discussions. Uses evidence from related geo-science disciplines to develop an integrative approach to understanding processes that lead to the chemical differentiation of planetary bodies through time. Subject matter may be modified to reflect the interests of the group.
T. L. Grove

12.492 Fundamentals of Stable Isotope Fractionation
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: None
Units: 2-4-6
Subject Cancelled Subject Cancelled
______
Designed for bio-geo-chemists to gain a first order understanding of the origin of stable isotope effects and their application in understanding important geochemical processes on earth and planets. Includes an introduction of relevant physical chemistry, simple numerical integration methods of time-forward modeling to solve isotope systematics of complex systems, and discussion of the latest as well as classic papers of the topic.
S. Ono

12.493[J] Microbial Genetics and Evolution
______

Graduate (Fall)
(Same subject as1.87[J],7.493[J],20.446[J])
Prereq: 7.03, 7.05, or permission of instructor
Units: 4-0-8
Lecture: TR12.30-2.30 (66-160)
______
Covers aspects of microbial genetic and genomic analyses, central dogma, horizontal gene transfer, and evolution.
A. D. Grossman, G. Fournier
Textbooks (Fall 2016)

Geophysics

12.501 Essentials of Global Geophysics
______

Not offered academic year 2017-2018Graduate (Fall)
(Subject meets with12.201)
Prereq: Physics II (GIR), 18.03
Units: 4-0-8
URL: http://quake.mit.edu/~fjsimons/12.201-12.501.html
Lecture: MWF9 (54-824) +final
______
Overview of basic topics in solid-earth geophysics, such as the Earth's rotation, gravity and magnetic field, seismology, and thermal structure. Formulation of physical principles presented in three one-hour lectures per week. Current applications discussed in an additional one-hour tutorial each week. Students taking graduate version complete different assignments.
R. van der Hilst
No textbook information available

12.507 Essentials of Applied Geophysics
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with12.214)
Prereq: 18.03
Units: 3-3-6
______
Introduces the application of geophysical methods to all aspects of near-surface environmental and engineering geophysics, including the exploration for petroleum, water, and minerals. Topics include seismic, electrical, electromagnetic, ground penetrating radar, magnetics, gravity, rock physics and chemistry, borehole geophysics and the global positioning system (GPS). Uses a quantitative approach to emphasize basic principles and a physical /chemical understanding of each method. Discusses specific illustrative field examples. Lab work is mainly devoted to local field work and equipment preparation for the IAP Field Geophysics class. Students taking graduate version complete additional assignments.
F. D. Morgan, T. A. Herring, B. H. Hager

12.510 Introduction to Seismology
______

Graduate (Spring)
Prereq: 18.075 or 18.085
Units: 3-1-8
______
A basic study in seismology and the utilization of seismic waves for the study of Earth's interior. Introduces techniques necessary for understanding of elastic wave propagation in stratified media and for calculation of synthetic seismograms (WKBJ and mode summation). Ray theory; interpretation of travel times. (e.g., tomography); surface wave dispersion in layered media; Earth's free oscillations; and seismicity, (earthquake locations, magnitude, moment, and source properties).
G. Prieto

12.511 Field Geophysics
______

Not offered academic year 2016-2017Graduate (IAP)
(Subject meets with12.221)
Prereq: None
Units: 1-4-1 [P/D/F]
______
Covers practical methods of modern geophysics, including the global positioning system (GPS), gravity, and magnetics. Field work is conducted in western US and includes intensive 10-day field exercise. Focuses on measurement techniques and their interpretation. Introduces the science of gravity, magnetics, and the GPS. Measures crustal structure, fault motions, tectonic deformations, and the local gravity and magnetic fields. Students perform high-precision measurements and participate in data analysis. Emphasizes principles of geophysical data collection and the relevance of these data for tectonic faulting, crustal structure, and the dynamics of the earthquake cycle. Students taking graduate version complete additional assignments.
T. A. Herring, B. H. Hager, F. D. Morgan

12.512 Field Geophysics Analysis
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with12.222)
Prereq: 12.511
Units: 2-0-4
______
Focuses on in-depth data analysis and development of skills needed to report results both in writing and orally. Students use data collected in 12.511 to develop written and oral reports of the results, with each student focusing on a different area. For example, students can develop the geophysical modeling or synthesis of the results into other studies in the area. The final written and oral reports are combined into a comprehensive report and presentation of the field camp and its results. Students taking graduate version complete additional assignments.
T. A. Herring, B. H. Hager, F. D. Morgan

12.515 Data and Models
______

Graduate (Fall)
Prereq: 18.075 or 18.085
Units: 3-0-9
Lecture: TR3-4.30 (54-824)
______
Surveys a number of methods of inverting data to obtain model parameter estimates. Topics include review of matrix theory and statistics, random and grid-search methods, linear and non-linear least squares, maximum-likelihood estimation, ridge regression, stochastic inversion, sequential estimation, singular value decomposition, solution of large systems, genetic and simulated annealing inversion, regularization, parameter error estimates, and solution uniqueness and resolution. Computer laboratory and algorithm development.
F. D. Morgan
No textbook information available

12.520 Geodynamics
______

Graduate (Spring)
Prereq: 12.005; 18.075 or 18.085
Units: 3-0-9
______
Mechanics of deformation of the crust and mantle, with emphasis on the importance of different rheological descriptions: brittle, elastic, linear and nonlinear fluids, and viscoelastic.
B. H. Hager

12.521 Computational Geophysical Modeling
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces theory, design, and practical methods of computational modeling in geodynamics and geophysical fluid dynamics. Covers the most effective and widely used numerical modeling approaches (e.g., boundary element, finite difference, finite element) and emphasizes problem-solving skills through illustrative examples of heat and mass transfer in the mantle and the ocean. Students acquire experience with various numerical methods through regularly assigned computational exercises and a term-long modeling project of each student's choice.
J. Lin, O. Marchal, M. Behn

12.522 Geological Fluid Mechanics
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 8.03; 18.075 or 18.085
Units: 3-0-9
______
Treats heat transfer and fluid mechanics in the Earth, low Reynolds number flows, convection instability, double diffusion, Non-Newtonian flows, flow in porous media, and the interaction of flows with accreting and deforming boundaries. Applications include: the flow under plates, postglacial rebound, diapirism, magma dynamics, and the mantle convection problem.
J. A. Whitehead (WHOI)

12.524 Mechanical Properties of Rocks
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 8.03, 18.03
Units: 3-0-9
Lecture: M4-5.30 (54-611)
______
A survey of the mechanical behavior of rocks in natural geologic situations. Topics: brief survey of field evidence of rock deformation, physics of plastic deformation in minerals, brittle fracture and sliding, and pressure-solution processes. Results of field petrologic and structural studies compared to data from experimental structural geology.
B. Evans
No textbook information available

12.525 Mechanisms of Faulting and Earthquakes
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Explores the fundamental mechanics of faulting and earthquakes from four related perspectives: seismology, geodesy, geodynamics, and rheology. Topics to be covered include (1) the physical processes that control the rheology of faults, including friction and fracture, (2) how these rheological processes are manifest in faulting and earthquakes in the earth from a geodynamics perspective, and (3) how the mechanics of faulting and earthquakes are constrained by seismological and geodetic observations. Both continental and oceanic examples of faulting and earthquakes will be featured.
J. Lin, J. McGuire, Y. Liu

12.533 Rock Physics
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-3-6
______
Fundamentals of experimental and theoretical rock physics taught at an advanced level. Rocks viewed as complex composite media with behavior dependent both on the physical and chemical properties of the constituent phases, and on their geometries. Electrical, fluid transport, and seismic properties covered in detail. Other topics such as magnetic, mechanical, and thermal responses briefly discussed. Weekly laboratory.
F. D. Morgan

12.540 Principles of Global Positioning System
______

Graduate (Spring)
Prereq: Physics I (GIR), Calculus II (GIR), 18.06
Units: 3-1-8
______
The principles and applications of the Global Positioning System (GPS) and other space geodetic systems, including very-long-baseline interferometry (VLBI) and satellite laser ranging (SLR). The nature and uses of the course acquisition (CA), the precise positioning (P) codes, and the differential carrier phase observable. Techniques for estimating geodetic and geophysical quantities from these data. Other topics include: atmospheric refraction modeling, effects of Selective Availability (SA), estimation techniques (including Kalman filtering). Statistical and spectral analysis of data.
T. A. Herring

12.552 Advanced Seismology: Theory and Applications of Seismic Imaging
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 12.510
Units: 3-0-9
______
Introduces fundamental principles of seismic imaging used in both exploration and solid earth applications. Topics include ray theoretical approaches, scattering theory, and seismic waveform modeling. Through lectures, projects and student-led discussions of journal articles, the class covers the whole process of seismic imaging, from data preprocessing to model generation and geological interpretation of the results.
EAPS Faculty

12.560-12.561 Advanced Seminar in Exploration Geophysics
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
______
Advanced seminar focusing on areas of current interest in exploration geophysics and seismology. 12.560 is letter-graded.
Geophysics Staff

12.570 Topical Issues in Global Geophysics
______

Not offered academic year 2017-2018Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
______
Series of formal lectures and seminars with the specific content varying by term to reflect current issues in research. Meets jointly with relevant Harvard course.
R. D. van der Hilst

12.571 Seminar in Geophysics
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
Subject Cancelled Subject Cancelled
______
Problems of current interest in geophysics; subject matter varying from term to term.
Geophysics Staff

12.580-12.581 Current Research in Geophysics
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.580: TBA.
12.581: TBA.
______
Original investigations, laboratory work, or fieldwork in geophysics. 12.580 is letter-graded.
Geophysics Staff
12.580: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.581: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.586 Modeling Environmental Complexity
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with12.086)
Prereq: 18.03 or permission of the instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduction to mathematical and physical models of environmental processes. Emphasis on the development of macroscopic continuum or statistical descriptions of complex microscopic dynamics. Problems of interest include: random walks and statistical geometry of landscapes; percolation theory and transport in disordered media; fractals, scaling, and universality; ecological dynamics and the structure of ecosystems, food webs, and other natural networks; kinetics of biogeochemical cycles. Appropriate for advanced undergraduates. Beginning graduate students are encouraged to register for 12.586. Students taking the graduate version complete different assignments.
D. H. Rothman


left arrow|12.00-12.439 plus UROP, IND, TIP, ThU|12.440-12.599 plus ThG|12.600-12.999|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 12: Earth, Atmospheric, and Planetary Sciences
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Course 12: Earth, Atmospheric, and Planetary Sciences
Fall 2016


Planetary Science

12.601 Essentials of Planetary Science
______

Not offered academic year 2016-2017Graduate (Fall)
(Subject meets with12.420)
Prereq: 8.03, 18.03
Units: 3-0-9
______
Reviews fundamental physical concepts pertaining to the study of the solar system, and highlights recent spacecraft results. Topics include: meteorites, orbital dynamics, asteroids, impact craters, surfaces, atmospheres, atmospheric dynamics, interiors, magnetospheres, rings, comets, formation of the solar system.
B. P. Weiss

12.602 Asteroids and Small Bodies
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Physics II (GIR), 18.03
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduction to the study of asteroids and the ground-based and space-based techniques used to explore them. Topics include asteroid orbital properties, surface structure, physical properties, classifications, as well as their origin, thermal and collisional evolution, and interrelationships with meteorites and comets. Also covers the near-Earth asteroids, the probabilities and consequences of terrestrial collisions, and the possible utilization of asteroids as space resources.
R. P. Binzel

12.603 Solar System Dynamics
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Studies the dynamics of the solar system and its major subsystems, and the dynamics of exoplanets, with a modern emphasis on the qualitative structure of phase space. Topics may include rotational dynamics, spin-orbit coupling, Cassini states, and orbital dynamics, resonances, and Kozai oscillations, tidal evolution and tidal heating.
J. Wisdom

12.611 Advanced Planetary Observations
______

Graduate (IAP) Can be repeated for credit
Prereq: Permission of instructor
Units: 0-6-3 [P/D/F]
______
Individual research projects in planetary science and astrophysics involving supervised work at Lowell Observatory in Flagstaff, AZ. Projects may include observations made using Lowell's telescope facilities. Project topics and objectives vary from year to year. Written and oral reports required. Enrollment limited.
A. Bosh

12.620[J] Classical Mechanics: A Computational Approach
______

Graduate (Fall)
(Same subject as6.946[J],8.351[J])
Prereq: Physics I (GIR), 18.03, permission of instructor
Units: 3-3-6
Credit cannot also be received for12.008
URL: http://groups.csail.mit.edu/mac/users/gjs/6946/index.html
Lecture: MWF11 (54-819) Lab: W EVE (7-10 PM) (14-0637)
______
Classical mechanics in a computational framework, Lagrangian formulation, action, variational principles, and Hamilton's principle. Conserved quantities, Hamiltonian formulation, surfaces of section, chaos, and Liouville's theorem. Poincaré integral invariants, Poincaré-Birkhoff and KAM theorems. Invariant curves and cantori. Nonlinear resonances, resonance overlap and transition to chaos. Symplectic integration. Adiabatic invariants. Applications to simple physical systems and solar system dynamics. Extensive use of computation to capture methods, for simulation, and for symbolic analysis. Programming experience required. Students taking the graduate version complete additional assignments.
J. Wisdom, G. J. Sussman
Textbooks (Fall 2016)

12.625 Extrasolar Planets: Physics and Detection Techniques
______

Graduate (Fall)
(Subject meets with8.290[J],12.425[J])
Prereq: 8.03, 18.03
Units: 3-0-9
Lecture: TR1.30-3 (54-824)
______
In-depth study of current topics in exoplanets, such as exoplanet transits, radial velocity curves, current survey missions, the mass-radius relation, and super Earths. Class activities consist of reading the current literature, problem sets, and a term project. Students taking graduate version complete additional assignments.
S. Seager
No textbook information available

12.650 Current Topics in Planetary Science
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
In-depth discussion of current and classic literature on selected topics in planetary science. Topics vary from year to year.
J. Wisdom

12.652 Current Topics in Planetary Science
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9 [P/D/F]
______
In-depth discussion of current and classic literature on selected topics in the specialty areas of asteroids and the Pluto-Charon system. Topics vary from year to year.
R. P. Binzel

12.690-12.691 Current Research in Planetary Science
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.690: TBA.
12.691: TBA.
______
Original investigations, laboratory work, or fieldwork in planetary science. 12.690 is letter-graded.
Planetary Science Staff
12.690: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.691: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

Geological, Geophysical, and Chemical Oceanography

12.701 Classic Papers in Physical Oceanography
______

Graduate (Spring)
Prereq: None
Units: 3-0-3 [P/D/F]
______
Provides a historical perspective on fundamental topics in oceanography by considering individual works which, when pieced together, contribute to the more cohesive description of how the ocean works. In class discussions, students consider various aspects of the work in question, including motivation, approach, and implications for the broader context. They also synthesize information and make oral presentations. Develops basic analytical and critical skills in paper reading and writing.
Y. Kwon (WHOI)

12.702 Elements of Modern Oceanography
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
TBA.
______
Examines a series of crosscutting topics that exemplify current directions in interdisciplinary oceanography. Focuses on current themes in oceanography, their inter-disciplinary nature, and the role of ocean sciences in society. Introduces core concepts across the disciplines of biological, physical, and chemical oceanography as well as marine geology. Emphasis on the inter-disciplinary aspects of these core concepts, the kinds of approaches and modes of thinking common to all of the disciplines, and the technological developments underpinning current advances.
G. Lawson, A. Kirincich (WHOI)
No textbook information available

12.703 Presenting Scientific Research
______

Graduate (Fall)
Prereq: None
Units: 3-0-3
TBA.
______
Presenting scientific research geared toward a scientific audience. Each student gives one 30-minute talk, one AGU-style 15-minute talk, and one poster presentation. Students present their ongoing research and use the class as a forum to practice for upcoming talks in more formal settings. Abstracts are prepared for each presentation and discussed in class. Students provide comments, questions, encouragement, critiques, etc. on their peers' presentations.
S. Nielsen, V. Le Roux (WHOI)
No textbook information available

12.707 The History of Earth's Climate
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Climate history of the Earth from the formation of the early atmosphere and ocean to the present. Evaluation of geochemical, sedimentological, and paleontological evidence for changes in ocean circulation, global temperatures, and atmospheric carbon dioxide levels. Theories and models of Phanerozoic climate change. Long-term history of the global carbon cycle.
D. McGee

12.708 Seminar in Paleoclimatology
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Advanced seminar focusing on areas of current interest in paleoceanography and paleoclimatology. Includes discussion of current and classic literature. Topics vary from year to year.
D. Oppo, O. Marchal (WHOI)
No textbook information available

12.710 Geological Oceanography
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
TBA.
______
Provides a high level survey of a broad range of active science topics in Geological Oceanography. Presents background material that graduate students are expected to know in the disciplines of solid-earth geophysics, geochemistry, sedimentology and stratigraphy, coastal processes, and climate, including a representative set of canonical science papers, and builds on this material to give a sense of the current state of the science in these fields. Broad topics include the formation of the earth, petrogenesis, volcanism, plate tectonics, geodynamics, sedimentation in the oceans, coastal morphodynamics, paleo-oceanography, and climate. The interconnectedness of and feedbacks between processes discussed under these various topics is emphasized.
WHOI Staff
No textbook information available

12.712 Advanced Marine Seismology
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-6
______
Focuses on synthetic seismograms, ocean bottom refraction seismology, and multi-channel reflection seismology as applied to studies of the ocean sediments, crust, and lithosphere. Topics include: the wave equations for elastic/anelastic, isotropic/anisotropic, homogeneous/heterogeneous and fluid/solid media; ray theory and WKBJ approximations; the Sommerfeld/Weyl integrals, asymptotic analysis, and Lamb's problem for a fluid/solid interface; reflectivity and related methods; finite difference and finite element methods; and special topics of interest to the class. Extensive readings of geophysical and seismological literature.
R. Stephen (WHOI)

12.714 Computational Data Analysis
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.03
Units: 3-0-9
______
An introduction to the theory and practice of analyzing discrete data such as are normally encountered in geophysics and geology. Emphasizes statistical aspects of data interpretation and the nonparametric discrete-time approach to spectral analysis. Topics include: elements of probability and statistics, statistical inference, robust and nonparametric statistics, the method of least squares, univariate and multivariate spectral analysis, digital filters, and aspects of multidimensional data analysis.
A. D. Chave, T. A. Herring

12.716 Essentials of Oceanic Petrology
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: 12.710 or permission of instructor
Units: 3-2-4
Subject Cancelled Subject Cancelled
______
Qualitative interpretation and quantitative analysis of melting, melt transport, melt-rock reactions, igneous crustal accretion, metamorphism and hydrothermalism at oceanic spreading centers and subduction-related arcs applied to understanding the variations in the composition of the Earth's (oceanic) mantle and crust and accretionalry processes at mid-ocean ridges. Combines theoretical methods with field, petrographic, geochemical, and computational techniques. Topics vary from year to year.
H. Dick, F. Klein, V. Le Roux (WHOI)

12.717 Coastal Geomorphology
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Explores mechanisms behind the formation and reshaping of coastal environments. Focuses on a process-based understanding of both the fluid dynamic and sediment transport aspects of coastal landforms, and, especially, the importance of feedbacks between the two. Investigates coastal evolution at various scales - from ripples to coastline formation - with an emphasis on the behavior of coastal environments over integrated timescales of days and years to centuries and millennia. Students investigate the effect of storms, sea-level rise, and interactions with biological and anthropogenic influences. Covers a broad array of coastal environments, including beaches, barrier islands, spits, inlets, tidal flats, deltas, rocky coasts, arctic shores, and carbonate atolls.
A. Ashton

12.718 Kinetics and Mass Transport
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
______
Offers a broad overview of various kinetic and transport processes in geology, including volume and grain boundary solid-state diffusion, defects in minerals, rates of mineral reaction and transformation, crystal nucleation and growth, advective transport in porous media and partially molten aggregates, and percolation theory. Emphasis on processes in crystalline rocks. Covers theoretical, phenomenological, and experimental constraints, with a consistent application to "real-world" settings and actual case histories.
M. Behn and G. Gaetani (WHOI)

12.721 Current Research in Marine Geology and Geophysics at Woods Hole
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Original investigations, laboratory work, or fieldwork in marine geology and geophysics.
WHOI Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.722 Current Research in Chemical Oceanography at Woods Hole
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Original investigations, laboratory work, or fieldwork in chemical oceanography.
WHOI Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.730-12.731 Current Research in Marine Geology and Geophysics at MIT
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.730: TBA.
12.731: TBA.
______
Original investigations, laboratory work, or fieldwork in marine geology and geophysics under the supervision of a faculty member in residence at MIT. For students in the MIT/WHOI Joint Program. 12.730 is letter-graded.
Marine Geology and Geophysics Staff
12.730: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.731: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.735-12.736 Current Research in Chemical Oceanography at MIT
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.735: TBA.
12.736: TBA.
______
Original investigations, laboratory work, or fieldwork in chemical oceanography under the supervision of a faculty member in residence at MIT. For students in the MIT/WHOI Joint Program. 12.735 is letter-graded.
Chemical Oceanography Staff
12.735: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.736: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.739 Marine Microbiology and Biogeochemistry
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: None
Units: 3-0-9
______
Integrates the fields of microbiology and biogeochemistry, and is centered on elucidating the linkages between microorganisms and geochemical processes in the oceans. Divided into modules that first lay the theoretical framework to familiarize students of diverse backgrounds (biologists, chemists, physical oceanographers). Next, introduces specific and general linkages between the topics and the major tools and techniques that have advanced their integrated study. Concludes with a synthesis module examining the role of microorganisms in the biogeochemical cycles of diverse ocean biomes
A. Apprill, S. Sievert (WHOI)

12.740 Paleoceanography
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Studies the basic principles of techniques for reconstructing the history of ocean climate from marine sediment cores, corals, ice cores, and other paleoclimate archives. Examines this data in the light of proposed climate change mechanisms. Micropaleontological, isotopic, geochemical, and mineralogical changes are used to infer changes in seawater composition, atmospheric chemistry, and climate. Observations are interpreted as consequences of changes in ocean temperature, circulation, and chemistry, and are used to evaluate theories proposed to account for glacial/interglacial cycles. Focuses on the past two million years, but major processes and events from the past 100 million years are also included.
E. A. Boyle

12.741 Marine Bioinorganic Chemistry
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of Instructor
Units: 2-0-7
______
Provides an overview of trace element biogeochemistry and marine bioinorganic chemistry. Topics include controls on oceanic trace metal distributions; co-evolution of biological metal requirements and metal availability during early Earth history; chemical speciation and its influence on microbial bioavailability; applications of metal isotopes; roles of metalloenzymes and metal proteins in biogeochemical cycles; and biogeochemical applications of metagenomics, metaproteomics, and bioinformatics.
M. Saito

12.742 Marine Chemistry
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
And clark 271 at WHOI. TBA.
______
An introduction to chemical oceanography. Reservoir models and residence time. Major ion composition of seawater. Inputs to and outputs from the ocean via rivers, the atmosphere, and the sea floor. Biogeochemical cycling within the oceanic water column and sediments, emphasizing the roles played by the formation, transport, and alteration of oceanic particles and the effects that these processes have on seawater composition. Cycles of carbon, nitrogen, phosphorus, oxygen, and sulfur. Uptake of anthropogenic carbon dioxide by the ocean. Material presented through lectures and student-led presentation and discussion of recent papers.
B. Van Mooy, S. Doney (WHOI)
No textbook information available

12.743 Geochemistry of Marine Sediments
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Chemistry (GIR), 5.60
Units: 3-0-9
______
Focuses on processes that control the composition of sediments in coastal, shelf, and deep-sea environments and processes that define their roles in biogeochemical cycles. Topics include calculating chemical fluxes across the sediment-water interface; evaluating the sources and reactivity of carbonate, silicic, and detrital sediments; using pore water gradients to calculate diffusion, reaction, and flux rates; sediment dating; estimating accumulation rates; and using stable isotopes and natural-series radioisotopes. Covers evaluation of the links between sedimentary and water column processes; the effects of anthropogenic disturbances (e.g., eutrophication, acidification, warming) on sedimentary processes; and the role of sediments in global biogeochemical cycles. Introduces sampling techniques and mathematical modeling of sedimentary processes.
D. McCorkle, W. Martin, A. Spivak (WHOI)

12.744 Marine Isotope Chemistry
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of the instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Fundamentals of using isotopes to study processes and timescales for marine chemistry and geochemistry. Starts with a basic introduction to the nature, origins, and reasons for the distributions of isotopes in nature, then develops theory and approaches for radioactive dating methods. These are used to constrain the timing and nature of the geochemical evolution of the elements, solar system, earth, ocean and atmosphere. Cosmogenic isotopes and their applications are covered. Basics of mass spectrometry are briefly discussed, and then the principles and applications of isotope fractionation are more thoroughly dealt with. Introduction to mass independent fractionation and clumped isotope methods. Explores applications of isotope methods to a number of water column processes, including particle scavenging, sedimentation, long term element budgets, redox processes, and air-sea exchange. Emphasis will be on quantitative methods and problem-solving, and there will be four problem sessions with development of problem solutions.
WHOI Staff

12.746 Marine Organic Geochemistry
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Provides an understanding of the distribution of organic carbon (OC) in marine sediments from a global and molecular-level perspective. Surveys the mineralization and preservation of OC in the water column and within anoxic and oxic marine sediments. Topics include: OC composition, reactivity and budgets within, and fluxes through, major reservoirs; microbial recycling pathways for OC; models for OC degradation and preservation; role of anoxia in OC burial; relationships between dissolved and particulate (sinking and suspended) OC; methods for characterization of sedimentary organic matter; application of biological markers as tools in oceanography. Both structural and isotopic aspects are covered.
D. Repeta, T. I. Eglinton (WHOI)

12.747 Modeling, Data Analysis, and Numerical Techniques for Geochemistry
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
TBA.
______
Emphasizes the basic skills needed for handling and assimilating data as well as the basic tool-set for numerical modeling. Uses MATLAB as its computation engine; begins with an introduction to MATLAB to ensure familiarity with software. Topics include: probability distributions, error propagation, least squares and regression techniques, principle component and factor analysis, objective mapping, Fourier and spectral analysis, numerical solutions to ODEs and PDEs, finite difference techniques, inverse models, and scientific visualization.
D. Glover, W. Jenkins, S. Doney (WHOI)
No textbook information available

12.749 Solid Earth Geochemistry
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Integrates methods in mineralogy, petrology (both igneous and metamorphic), and trace element and isotope geochemistry to address scientific issues of the solid earth. Covers processes in the solar nebula, accretion, and early differentiation of the earth. Discusses topics in three representative geodynamic environments - mid-ocean ridges, subduction zones, and mantle plumes - with respect to physical framework and petrological/geochemical aspects.
N. Shimizu, S. Nielsen (WHOI)

12.751-12.759 Seminar in Oceanography at Woods Hole
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.754: TBA.
Subject Cancelled 12.757 Cancelled
______
Topics in marine geology and geophysics, physical, dynamical, and chemical oceanography. Content varies from term to term. 12.754, 12.755, and 12.756 are letter-graded.
WHOI Staff
12.754: No textbook information available

12.760-12.761 Seminar in Marine Geology and Geophysics at MIT
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Topics in marine geology and geophysics taught at MIT. Content varies from term to term. 12.760 is letter-graded.
Marine Geology and Geophysics Staff

12.770-12.771 Seminar in Chemical Oceanography at MIT
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Topics in chemical oceanography taught at MIT. Content varies from term to term. 12.770 is letter-graded.
Chemical Oceanography Staff

Atmospheres, Oceans, and Climate

12.800 Fluid Dynamics of the Atmosphere and Ocean
______

Graduate (Fall)
Prereq: 8.03, 18.04
Units: 3-0-9
MIT and clark 331 at WHOI. Lecture: MW9-10.30 (54-1623) +final
______
Introduction to fluid dynamics. Students acquire an understanding of some of the basic concepts of fluid dynamics that are needed as a foundation for advanced courses in atmospheric science, physical oceanography, ocean engineering, climate science, etc. Emphasizes fluid fundamentals, with an atmosphere/ocean twist.
J. Marshall
Textbooks (Fall 2016)

12.801 Large-scale Ocean Dynamics
______

Graduate (Spring)
Prereq: 12.800
Units: 3-0-9
______
Applies fundamental principles of geophysical fluid dynamics to understand the general patterns of the ocean circulation and stratification. Includes the mid-latitude wind-driven circulation, the Southern Ocean circulation, and the global overturning circulation. Uses a combination of theory, numerical simulations, and observations to illustrate the concepts.
R. Ferrari

12.802 Small-scale Ocean Dynamics
______

Graduate (Spring)
Prereq: 12.800
Units: 3-0-9
______
Basic ideas of geophysical wave motion in rotating, stratified, and rotating-stratified fluids. Subject begins with general wave concepts of phase and group velocity. The dynamics and kinematics of gravity waves with a focus on dispersion, energy flux, initial value problems, etc. Subject foundation used to study internal and inertial waves, Kelvin, Poincare, and Rossby waves in homogeneous and stratified fluids. Laplace tidal equations are applied to equatorial waves. Other topics include: resonant interactions, potential vorticity, wave-mean flow interactions, and instability.
G. Flierl and P. O'Gorman

12.805 Data Analysis in Physical Oceanography
______

Graduate (Spring)
Prereq: 12.808
Units: 3-0-6
______
Introduction to standard data analysis methods, including time series analysis, objective mapping, and empirical orthogonal functions. Focuses on working with data in a computer laboratory setting. Emphasizes how statistical information can be used to improve experimental design. Some attention given to the instruments and algorithms used to acquire the data.
G. Gebbie

12.806[J] Atmospheric Physics and Chemistry
______

Graduate (Spring)
(Same subject as10.571[J])
(Subject meets with12.306)
Prereq: 5.60 or 5.61; 18.075; or permission of instructor
Units: 3-0-9
______
Introduction to the physics and chemistry of the atmosphere including experience with computer codes. Aerosols and theories of their formation, evolution, and removal. Gas and aerosol transport from urban to continental scales. Coupled models of radiation, transport, and chemistry. Solution of inverse problems to deduce emissions and removal rates. Emissions control technology and costs. Applications to air pollution and climate.
R. G. Prinn

12.807[J] Atmospheric Chemistry
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as1.84[J], 10.817[J])
Prereq: 5.60
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Provides a detailed overview of the chemical transformations that control the abundances of key trace species in the Earth's atmosphere. Emphasizes the effects of human activity on air quality and climate. Topics include photochemistry, kinetics, and thermodynamics important to the chemistry of the atmosphere; stratospheric ozone depletion; oxidation chemistry of the troposphere; photochemical smog; aerosol chemistry; and sources and sinks of greenhouse gases and other climate forcers.
J. H. Kroll

12.808 Introduction to Observational Physical Oceanography
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
TBA.
______
Results and techniques of observations of the ocean in the context of its physical properties and dynamical constraints. Emphasis on large-scale steady circulation and the time-dependent processes that contribute to it. Includes the physical setting of the ocean, atmospheric forcing, application of conservation laws, description of wind-driven and thermohaline circulation, eddy processes, and interpretive techniques.
M. Andres, G. Gebbie (WHOI)
No textbook information available

12.809 Hydraulic Phenomena in Geophysical Fluid Flows
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
______
Examination of the hydraulics of nonrotating flows (Long's experiments, hydraulic control, upstream influence, nonlinear wave steepening, hydraulic jump and bores, application to severe downslope winds). Other topics may include: nonrotating stratified flows (two-layer hydraulics, virtual and approach controls, maximal and submaximal flow, application to the Strait of Gibraltar and the Bab al Mandab); and deep ocean straits and sills (steady theories for rotating channel flow, nonlinear Kelvin and frontal waves, rotating hydraulic jumps, geostrophic adjustment in a rotating channel, and applications to the Denmark Strait and other deep passages).
L. Pratt, K. Helfrich (WHOI)

12.810 Dynamics of the Atmosphere
______

Graduate (Spring)
Prereq: 12.800
Units: 3-0-9
URL: http://www.mit.edu/~pog/810.html
______
Discusses the dynamics of the atmosphere, with emphasis on the large scale. Topics include zonally symmetric circulations and the tropical Hadley circulation; internal gravity waves; balanced flows, potential vorticity conservation and Rossby waves; stability of zonal flows; baroclinic instability and extratropical storms; tropical waves, the Walker circulation, and El Niño and the Southern Oscillation; and the role of eddies in the general circulation. Students taking graduate version complete different assignments.
R. A. Plumb

12.811 Tropical Meteorology
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 12.810 orCoreq: 12.843
Units: 3-0-9
______
A description of the large-scale circulation systems of the tropical atmosphere and analysis of the dynamics of such systems. Topics include: Radiative-convective equilibrium; the Hadley and walker circulation; monsoons; tropical boundary layers; theory of the response of the tropical atmosphere to localized sea-surface temperature anomalies; intraseasonal oscillations; equatorial waves; El Niño/Southern Oscillation; easterly waves; and tropical cyclones.
K. A. Emanuel

12.812 The General Circulation of the Atmosphere and Climate Change
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 12.843 or permission of instructor
Units: 3-0-9
______
Explains the main features of the general circulation of the Earth's atmosphere. Final part of the course explores possible changes in the general circulation associated with climate change.
P. O'Gorman

12.814[J] Aerosol and Cloud Microphysics and Chemistry
______

Graduate (Spring)
(Same subject as1.842[J])
(Subject meets with12.338)
Prereq: Permission of instructor
Units: 3-0-9
______
Focuses on understanding how aerosol particles form droplets or ice crystals during several atmospheric processes: determining Earth's radiative balance; heterogeneous chemistry and acid rain; understanding where, when and how much precipitation occurs. Provides tools for understanding the physics of aerosol and cloud element motion; the interaction of particles with water vapor, including phase changes and droplet and ice nucleation; the chemical composition of particles and the effect on cloud formation processes; and the effect of cloud processing on aerosol chemistry. Discusses relevant topics of contemporary interest, e.g., geoengineering and weather modification and volcanic effects. Students taking the graduate version complete different assignments.
D. Cziczo

12.815 Atmospheric Radiation and Convection
______

Graduate (Fall)
Prereq: 5.61, 12.800, 18.075, or permission of instructor
Units: 5-2-5
Lecture: MW10.30-12 (54-824)
______
Introduction to the physics of atmospheric radiation, remote sensing, and convection, including use of computer codes. Radiative transfer equation including emission and scattering, spectroscopy, Mie theory, and numerical solutions. Physics of dry and moist convection, including moist thermodynamics. Radiative-convective equilibrium. Solution of inverse problems in remote sensing of atmospheric temperature and composition.
T. Cronin
Textbooks (Fall 2016)

12.817[J] Atmospheric Composition in the Changing Earth System
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as1.841[J])
Prereq: 1.84
Units: 3-0-9
______
Explores how atmospheric chemical composition both drives and responds to climate, with a particular focus on feedbacks via the biosphere. Topics include atmospheric nitrogen; DMS, sulfate, and CLAW; biogenic volatile organic compounds and secondary organic aerosol; wildfires and land use change; atmospheric methane and the oxidative capacity of the troposphere; and air quality and climate and geoengineering.
C. Heald

12.818 Introduction to Atmospheric Data and Synoptic Meteorology
______

Graduate (Fall)
Prereq: None.Coreq: 12.800
Units: 3-3-6
Lecture: TR12-1.30 (54-1623)
______
Provides a general introduction to meteorological data and analysis techniques, and their use in the MIT Synoptic Laboratory to study the phenomenology and dynamics of large-scale atmospheric flow. Balance concepts as applied to the dynamics of frontal and synoptic scales are illustrated using real-time upper air and surface station data and gridded analyzed fields. Advanced meteorological software packages are used to access, manipulate, and graphically display the data.
L. Illari
No textbook information available

12.820 Turbulence in the Ocean and Atmosphere
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 12.843
Units: 3-0-9
______
Covers phenomena, theory and modeling of turbulence in the Earth's oceans and atmosphere. The scope will range from centimeter- to planetary-scale motions. Includes homogeneous isotropic three- and two-dimensional turbulence, convection, stratified turbulence, quasi-gesotrophic turbulence, baroclinic turbulence, and macroturbulence in the ocean and atmosphere.
R. Ferrari, G. Flierl

12.823 Modeling the Biology and Physics of the Ocean
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 18.075 or 18.085
Units: 3-0-6
______
Principles and examples of the construction of physical/ biological models for oceanic systems. Individual-based and continuum representations. Food webs and structured population models. Fluid transport, stirring, and mixing. Effects of rotation and stratification. Advection, diffusion, reaction dynamics. Oceanic examples of physical-biological dynamics: surface mixed layer, upwelling regimes, mesoscale eddies, and oceanic gyres.
G. Flierl, D. McGillicuddy

12.824 Stability Theory for Oceanic & Atmospheric Flows
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 12.802 or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Basic theory of hydrodynamic instability with special application to flows of interest in oceanography and meteorology. Topics covered include general formulation of stability theory; concept of normal modes and linearization; fundamental stability theorems; baroclinic instability: Charney model, Eady model and the Phillips two-layer model; energy transformations; initial value theory and non-modal instability; barotropic instability for jets and shear layers; radiating instabilities; initial value problems applied to the concepts of convective, absolute and spatial instabilities; finite amplitude theory; stability of non-parallel flows.
G. Flierl

12.830 Topics in Waves and Instability
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 12.843
Units: 3-0-9
______
A detailed presentation of selected advanced topics in waves and instability in the atmosphere. The precise selection varies from year to year. Topics have included wave-mean flow interaction, the quasi-biennial oscillation, sudden warmings, critical-level behavior, wave overreflection, nonlinear equilibration, wave breaking, tropical waves, and stationary waves.
EAPS Staff

12.835 Experimental Atmospheric Chemistry
______

Graduate (Fall)
(Subject meets with12.335)
Prereq: Permission of instructor
Units: 2-4-6
Lecture: TR1.30-3 (54-1623)
______
Introduces the atmospheric chemistry involved in climate change, air pollution, and ozone depletion using a combination of interactive laboratory and field studies and simple computer models. Uses instruments for trace gas and aerosol measurements and methods for inferring fundamental information from these measurements. Students taking the graduate version complete different assignments.
R. Prinn, S. Ono, K. Dryer
No required or recommended textbooks

12.842 Climate Science
______

Graduate (Fall)
(Subject meets with12.301)
Prereq: Chemistry (GIR), 18.03, or permission of instructor
Units: 4-0-8
Lecture: MWF2 (54-824)
______
Introduction to climate studies, including beginnings of the solar system, time scales, and climate in human history; methods for detecting climate change, including proxies, ice cores, instrumental records, and time series analysis; physical and chemical processes in climate, including primordial atmosphere, ozone chemistry, carbon and oxygen cycles, and heat and water budgets; internal feedback mechanisms, including ice, aerosols, water vapor, clouds, and ocean circulation; climate forcing, including orbital variations, volcanism, plate tectonics, and solar variability; climate models and mechanisms of variability, including energy balance, coupled models, and global ocean and atmosphere models; and outstanding problems. Students taking the graduate version complete different assignments.
K. Emanuel, E. Boyle, D. McGee
Textbooks (Fall 2016)

12.843 Large-scale Atmosphere and Ocean Dynamics
______

Graduate (Fall)
Prereq: 12.801, 12.810, or permission of instructor
Units: 2-4-9
Lecture: WF1 (54-823) Lab: MR3-5 (54-1527) Recitation: M1 (54-823)
______
Project-based with lectures covering the relevant theory. Students work in groups on four projects. Each of these comprises a numerical part, to illuminate and illustrate the theory, and a data part (drawn from laboratory tank experiments, atmospheric, or ocean observations), to illustrate the phenomena. Topics include: barotropic vorticity dynamics including inversion and evolution, geostrophic and higher order balance, baroclinic dynamics and the evolution of balanced flows, and stability with emphasis on the mutual interaction of disturbances. Projects include a verbal presentation and writeup covering both the numerical and geophysical parts plus additional derivations as needed.
G. Flierl, L. Illari
No required or recommended textbooks

12.844[J] Modeling and Assessment for Policy
______

Graduate (Spring)
(Same subject asIDS.410[J])
Prereq: None
Units: 3-0-6
______
Explores how scientific information and quantitative models can be used to inform policy decision-making. Develops an understanding of quantitative modeling techniques and their role in the policy process through case studies and interactive activities. Addresses issues such as analysis of scientific assessment processes, uses of integrated assessment models, public perception of quantitative information, methods for dealing with uncertainties, and design choices in building policy-relevant models. Examples focus on models and information used in Earth system governance.
N. E. Selin

12.845[J] Sustainability Science and Engineering
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject asIDS.526[J])
Prereq: None
Units: 3-0-6
______
Introduces and develops core ideas and concepts in the field of sustainability science and engineering from an engineering systems perspective. Takes an interdisciplinary approach to discuss case studies of sustainability systems research. Exposes students to techniques for sustainability research across engineering, natural and social science disciplines. Term projects focus on applying techniques.
N. E. Selin

12.846[J] Global Environmental Negotiations
______

Graduate (Fall)
(Same subject asIDS.525[J])
(Subject meets with12.346[J],IDS.062[J])
Prereq: None
Units: 2-0-4
Lecture: T2.30-4.30 (4-144)
______
Practical introduction to global environmental negotiations designed for science and engineering students. Covers basic issues in international negotiations, such as North-South conflict, implementation and compliance, trade, and historical perspective on global environmental treaties. Offers hands-on practice in developing and interpreting international agreements through role-play simulations and observation of ongoing climate change negotiating processes. Students taking graduate version complete additional assignments.
N. Selin
Textbooks (Fall 2016)

12.848[J] Global Climate Change: Economics, Science, and Policy
______

Graduate (Spring)
(Same subject as15.023[J])
(Subject meets with12.348[J],15.026[J])
Prereq: Calculus II (GIR); 5.60; 14.01 or 15.010; or permission of instructor
Units: 3-0-6
______
Introduces scientific, economic, and ecological issues underlying the threat of global climate change, and the institutions engaged in negotiating an international response. Develops an integrated approach to analysis of climate change processes, and assessment of proposed policy measures, drawing on research and model development within the MIT Joint Program on the Science and Policy of Global Change. Graduate students are expected to explore the topic in greater depth through reading and individual research.
R. G. Prinn

12.849 Mechanisms and Models of the Global Carbon Cycle
______

Graduate (Spring)
(Subject meets with12.349)
Prereq: Permission of instructor
Units: 3-0-9
______
Addresses changes in the ocean, terrestrial biosphere and rocks modulation of atmospheric carbon dioxide on timescales from months to millions of years. Includes feedbacks between carbon cycle and climate. Combines hands-on data analysis with the formulation of simple models rooted in basic physical, chemical and biological principles. Students create individual "toy" global carbon cycle models. Students taking graduate version complete different assignments.
M. Follows

12.850 Computational Ocean Modeling
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: None
Units: 3-0-9
______
Numerical modeling in oceanography and environmental fluid mechanics. Focuses on the building of computational models that describe processes such as transport (advection, diffusion), reaction (ecosystems), and boundary forcing, of relevance in the ocean. Models are developed in a hierarchical manner, starting from the simple (zero-dimensional in space), and incrementally advancing toward more complex, time-evolving systems in one-, two- (shallow water) and three-dimensions (Primitive equations). Students build their own models using the finite volume approach with an appreciation and understanding of the working of general circulation models
A. Mahadevan (WHOI)

12.853 Advanced geophysical fluid dynamics
______

Graduate (Fall)
Prereq: 12.843 or permission of instructor
Units: 2-0-7
TBA.
______
Follow-on to 12.843, with a more mathematical treatment and extension of material to current topics of interest involving rotating, stratified flows of oceans and atmospheres.
G. Flierl
No textbook information available

12.860 Climate Variability and Diagnostics
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Practical insight into characteristics and mechanisms of climate variability from regional to global scale in the modern world with applications to past and future climates. Major emphasis is placed on the salient features of the mean climate system and their dominant modes of natural variability (e.g., El Nino-Southern Oscillation, North Atlantic Oscillation) as well as observed and projected manifestations of anthropogenic climate change. Learning is driven by exploration of data and supplemented by lectures and published literature. Through inter-active learning students gain experience accessing and analyzing a wide range of gridded data including instrumental, satellite, and reanalysis products as well as IPCC global climate model simulations.
C. Uhmmenhofer

12.862 Coastal Physical Oceanography
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 12.800
Units: 3-0-9
TBA.
______
Introduction to the dynamics of flow over the continental shelf, nearshore, and estuaries, emphasizing both theory and observations. Content varies somewhat according to student and staff interests. Possible topics include fronts, buoyant plumes, surface and bottom boundary layers, wind-driven upwelling, coastal-trapped waves, internal waves, quasi-steady flows, high-latitude shelf processes, tides, and shelf-open ocean interactions.
R. Todd, D. Ralston (WHOI)
No textbook information available

12.863 Advanced Topics in Coastal Physical Oceanography
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 12.862 or permission of instructor
Units: 3-0-6
______
More specialized topics in the dynamics of flow over the continental shelf, including coastal-trapped waves, wind-driving, and mean flows. Emphasis on the relationship between theory and observations. Instrumentation and the application of statistical techniques also covered.
Woods Hole Staff

12.866 Theory of the General Circulation of the Ocean
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 12.800, 12.801, 12.802
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
A review of wind-driven circulation, and the development of the baroclinic theory of the wind-driven circulation. Potential vorticity homohenization and the ventilated thermocline. Wind-driven circulation with continuous stratification, subduction/obduction. Equatorial thermocline and its relation to ENSO. Decadal climate variability. Thermohaline circulation and variability. Abyssal circulation. Mixing and energetics of the oceanic general circulation.
R. X. Huang (WHOI)

12.870 Air-Sea Interaction: Boundary Layers
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Graduate-level fluid mechanics and a subject on waves, or permission of instructor
Units: 3-0-9
TBA.
______
Addresses the interaction of the atmosphere and ocean on temporal scales from seconds to days and spatial scales from centimeters to kilometers. Topics include the generation, propagation, and decay of surface waves; the processes by which mass, heat, momentum, and energy are transported vertically within the coupled atmospheric and oceanic boundary layers and across the air-sea interface; and the statistical tools, mathematical models, and observational methods that are used to quantify these processes.
J. Trowbridge, E. Terray (WHOI)
No textbook information available

12.885[J] Science, Politics, and Environmental Policy
______

Graduate (Fall)
(Same subject as11.373[J])
(Subject meets with12.385)
Prereq: Permission of instructor
Units: 3-0-6
Lecture: M EVE (3-6 PM) (54-1623)
______
Examines the role of science in US and international environmental policymaking. Surveys the methods by which scientists learn about the natural world; the treatment of science by experts, advocates, the media, and the public and the way science is used in legislative, administrative and judicial decision making. Through lectures, group discussions, and written essays, students develop a critical understanding of the role of science in environmental policy. Potential case studies include fisheries management, ozone depletion, global warming, smog, and endangered species. Students taking the graduate version complete different assignments.
S. Solomon, J. Knox-Hayes
No required or recommended textbooks

12.950, 12.951 Seminar in Physical Oceanography at MIT
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Topics in physical and dynamical oceanography. Content varying from term to term. 12.950 is letter-graded.
Physical Oceanography Staff

12.960, 12.961 Current Research in Physical Oceanography at MIT
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.960: TBA.
12.961: TBA.
______
Original investigations, laboratory work, or fieldwork in oceanography. 12.960 is letter-graded.
Physical Oceanography Staff
12.960: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.961: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.970, 12.971 Current Research in Physical Oceanography at Woods Hole
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.970: TBA.
12.971: TBA.
______
Original investigations, laboratory work, or field work on oceanographic problems. 12.970 is letter-graded.
Woods Hole Staff
12.970: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.971: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.980, 12.981 Current Research in Atmospheric Science
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.980: TBA.
12.981: TBA.
______
Original investigations on problems in atmospheric science. 12.980 is letter-graded.
EAPS Staff
12.980: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.981: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.982, 12.983 Current Research in Climate Physics and Chemistry
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.982: TBA.
12.983: TBA.
______
Original investigations, laboratory work, or fieldwork in problems related to climate. 12.982 is letter-graded
PAOC faculty
12.982: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
12.983: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

12.S488, 12.S489 Special Seminar in Structural Geology
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Organized lecture or laboratory subject on an aspect of structural geology not normally covered in regularly scheduled subjects. 12.488 is letter-graded.
Geology and Geochemistry Staff

12.S490, 12.S491 Special Seminar in Geology and Geochemistry
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Organized lecture or laboratory subject on an aspect of geology or geochemistry not normally covered in regularly scheduled subjects. 12.490 is letter-graded.
Geology and Geochemistry Staff

12.S492, 12.S493 Special Seminar in Geobiology
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Organized lecture or laboratory subject on an aspect of geobiology not normally covered in regularly scheduled subjects. 12.492 is letter-graded.
Geobiology Staff

12.S590, 12.S591 Special Seminar in Geophysics
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Organized lecture or laboratory subject on an aspect of geophysics not normally covered in regularly scheduled subjects. 12.S590 is letter-graded.
Consult EAPS Education Office

12.S592, 12.S593 Special Seminar in Earth, Atmospheric and Planetary Sciences
______

Not offered academic year 2016-2017Graduate (IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.S593: URL: http://eapsweb.mit.edu/academics/courses/seminars
______
Organized lecture or laboratory subject on an aspect of the earth sciences, planetary sciences, or astronomy not normally covered in regularly scheduled subjects. 12.592 is letter-graded.
EAPS Staff

12.S680, 12.S681 Special Seminar in Planetary Science
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
12.S680: URL: http://eapsweb.mit.edu/academics/courses/seminars
12.S680: Friday class meets in 54-824. Lecture: TF10-11.30 (54-1623)
______
Organized lecture or laboratory subject on an aspect of planetary science not normally covered in regularly scheduled subjects. 12.S680 is letter-graded.
Planetary Science Staff
12.S680: No textbook information available

12.S990, 12.S991 Special Subject in Atmospheric Science
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
12.S990: URL: http://eapsweb.mit.edu/academics/courses/seminars
______
Organized lecture or laboratory subject on an aspect of atmospheric science not normally covered in regularly scheduled subjects. 12.S990 is letter-graded.
PAOC Staff

12.S992, 12.S993 Special Subject in Climate Physics and Chemistry
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
12.S993: URL: http://eapsweb.mit.edu/academics/courses/seminars
12.S993: Lecture: F9 (54-915)
______
Organized lecture or laboratory subject on an aspect of climate not normally covered in the regularly scheduled subjects. 12.S992 is letter-graded.
PAOC Staff
12.S993: No textbook information available


left arrow|12.00-12.439 plus UROP, IND, TIP, ThU|12.440-12.599 plus ThG|12.600-12.999|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 14: Economics
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Course 14: Economics
Fall 2016


General Economics and Theory

14.003 Microeconomic Theory and Public Policy
______

Graduate (Fall, Spring)
(Subject meets with14.03)
Prereq: 14.01 or permission of instructor
Units: 4-0-8
Lecture: MW9.30-11 (E52-164) Recitation: F9 (4-237) or F10 (4-237) +final
______
Applies microeconomic theory to analysis of public policy. Builds from microeconomic model of consumer behavior; extends to operation of single and multiple markets and analysis of why markets sometimes fail. Empirical examples to evaluate theory, focusing on the casual effects of policy interventions on economic outcomes. Topics include minimum wages and employment, food stamps and consumer welfare, economics of risk and safety regulation, the value of education, and gains from international trade. Graduate students are expected to complete additional assignments.
Fall:D. Autor
Spring:S. Kerr
Textbooks (Fall 2016)

14.01 Principles of Microeconomics
______

Undergrad (Fall, Spring) HASS Social Sciences
Prereq: None
Units: 3-0-9
Lecture: MW3 (E25-111) Recitation: F10 (5-134) or F11 (5-217) or F12 (5-217) or F1 (1-135) or F3 (4-270) or MWF11 (1-190) or MWF1 (35-308) +final
______
Introduces microeconomic concepts and analysis, supply and demand analysis, theories of the firm and individual behavior, competition and monopoly, and welfare economics. Applications to problems of current economic policy. Taught in two formats - lecture/recitation and recitation only - each with 3 sessions per week. Same content and exams.
Fall:C. Rothschild
Spring:J. Harris
Textbooks (Fall 2016)

14.02 Principles of Macroeconomics
______

Undergrad (Fall, Spring) HASS Social Sciences
Prereq: None
Units: 3-0-9
Lecture: MW2 (10-250) Recitation: F12 (1-190) or F1 (1-190) or MWF10 (35-308) or MWF11 (35-308)
______
Provides an overview of macroeconomic issues: the determination of output, employment, unemployment, interest rates, and inflation. Monetary and fiscal policies are discussed. Important current policy debates such as the sub-prime crisis, social security, the public debt, and international economic issues are critically explored. Introduces basic models of macroeconomics and illustrates principles with the experience of the US and foreign economies. Taught in two formats - lecture/recitation and recitation only - each with 3 sessions per week. Same content and exams.
Fall:R. Caballero
Spring:J. Poterba
Textbooks (Fall 2016)

14.03 Microeconomic Theory and Public Policy
______

Undergrad (Fall, Spring) HASS Social Sciences
(Subject meets with14.003)
Prereq: 14.01
Units: 4-0-8
Lecture: MW9.30-11 (E52-164) Recitation: F9 (4-237) or F10 (4-237) +final
______
Applies microeconomic theory to analysis of public policy. Builds from microeconomic model of consumer behavior; extends to operation of single and multiple markets and analysis of why markets sometimes fail. Empirical examples to evaluate theory, focusing on the casual effects of policy interventions on economic outcomes. Topics include minimum wages and employment, food stamps and consumer welfare, economics of risk and safety regulation, the value of education, and gains from international trade.
Fall:D. Autor
Spring:S. Kerr
Textbooks (Fall 2016)

14.04 Intermediate Microeconomic Theory
______

Undergrad (Spring) HASS Social Sciences
Prereq: 14.01, Calculus II (GIR)
Units: 4-0-8
______
Analysis of consumer and producer decisions including analysis of competitive and monopolistic markets. Price-based partial and general equilibrium analysis. Introduction to game theory as a foundation for the strategic analysis of economic situations. Imperfect competition, dynamic games among firms. Failures of general equilibrium theory and their resolutions: externalities, public goods, incomplete information settings, signaling, screening, insurance, alternative market mechanisms, auctions, design of markets.
J. Toikka

14.05 Intermediate Macroeconomics
______

Undergrad (Spring) HASS Social Sciences
Prereq: 14.01, 14.02
Units: 4-0-8
______
Uses the tools of macroeconomics to investigate various macroeconomic issues in depth. Topics range from economic growth and inequality in the long run to economic stability and financial crises in the short run. Surveys many economic models used today. Requires a substantial research paper on the economics of long-run economic growth.
A. Simsek

14.06 Advanced Macroeconomics
______

Undergrad (Fall) HASS Social Sciences
Prereq: 14.01, 14.02
Units: 4-0-8
Lecture: TR10.30-12 (E51-151) Recitation: F10 (E51-151) +final
______
Blends a thorough study of the theoretical foundations of modern macroeconomics with a review of useful mathematical tools, such as dynamic programming, optimal control, and dynamic systems. Develops comfort with formal macroeconomic reasoning and deepens understanding of key macroeconomic phenomena, such as business cycles. Goes on to study more specific topics, such as unemployment, financial crises, and the role of fiscal and monetary policy. Special attention to reviewing relevant facts and disentangling them from their popular interpretations. Uses insights and tools from game theory. Includes applications to recent and historical events.
G. M. Angeletos
Textbooks (Fall 2016)

14.08 Technical Topics in Economics
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: 14.01
Units: 4-0-8
TBA.
______
Considers technical issues of current research interest in economics.
Consult Department Headquarters
No required or recommended textbooks

14.09 Reading Seminar in Economics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 14.04, 14.06
Units arranged [P/D/F]
TBA.
______
Reading and discussion of particular topics in economics. Open to undergraduate students by arrangement with individual faculty members. Consult Department Headquarters.
A. Mikusheva
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

14.10 Reading Seminar in Economics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 14.04, 14.06
Units arranged
TBA.
______
Reading and discussion of particular topics in economics. Open to undergraduate students by arrangement with individual faculty members. Consult Department Headquarters.
A. Mikusheva
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

14.11 Topics in Economics
______

Undergrad (Fall) HASS Social Sciences Can be repeated for credit
Prereq: 14.01
Units: 4-0-8
Lecture: TR2.30-4 (1-190) Recitation: F10 (1-190)
______
Considers issues of current research interest in economics.
S. Heller
No required or recommended textbooks

14.12 Economic Applications of Game Theory
______

Undergrad (Fall) HASS Social Sciences
Prereq: 14.01; 6.041B or permission of instructor
Units: 4-0-8
Lecture: TR2.30-4 (E52-164) Recitation: F10 (E52-164) or F2 (E51-395) or F3 (E51-395) +final
______
Analysis of strategic behavior in multi-person economic settings. Introduction to solution concepts, such as rationalizability, backwards induction, Nash equilibrium, subgame-perfect equilibrium, and sequential equilibrium, with a strong emphasis on the assumptions behind these solution concepts. Issues of incomplete information, such as signaling and reputation formation. Applications drawn from microeconomics and political economy.
M. Yildiz
Textbooks (Fall 2016)

14.121 Microeconomic Theory I
______

Graduate (Fall); first half of term
Prereq: 14.04, permission of instructor
Units: 3-0-3
Ends Oct 21. Lecture: MW1-2.30 (E51-395) Recitation: F1-2.30 (E51-057)
______
Covers consumer and producer theory, uncertainty, and markets and competition. Studies the tools of comparative statics and their application to price theory. Enrollment limited; preference to PhD students.
A. Wolitzky
Textbooks (Fall 2016)

14.122 Microeconomic Theory II
______

Graduate (Fall); second half of term
Prereq: 14.121, permission of instructor
Units: 3-0-3
Begins Oct 24. Lecture: MW1-2.30 (E51-395) Recitation: F1-2.30 (E51-057) +final
______
Introduction to game theory. Topics include normal form and extensive form games, and games with incomplete information. Enrollment limited.
G. Ellison
Textbooks (Fall 2016)

14.123 Microeconomic Theory III
______

Graduate (Spring)
Prereq: 14.121, 14.122, permission of instructor
Units: 3-0-3
______
General equilibrium theory, a framework linking together micro and macroeconomics, and economic science. Covers Walrasian equilibrium (existence and computation, first and second welfare theorems); general implementation (the core, Nash bargaining, strategic market games); the representative consumer and Gorman aggregation; measurement and the organization of data; and calibration and econometric identification. Applications include uncertainty (risk sharing and financial markets); contracts and information economics; village economies and national development; models with money and credit; trade, spatial economics and differentiated commodities. Enrollment limited.
D. Fudenberg

14.124 Microeconomic Theory IV
______

Graduate (Spring)
Prereq: 14.123, permission of instructor
Units: 3-0-3
______
Decision-making under uncertainty, information economics, incentive and contract theory. Enrollment limited.
B. Holmstrom

14.125 Market Design
______

Graduate (Spring)
Prereq: 14.124
Units: 4-0-8
______
Theory and practice of market design, building on ideas from microeconomics, game theory and mechanism design. Prominent case studies include auctions, labor markets, school choice, prediction markets, financial markets, and organ exchange clearinghouses.
P. Pathak

14.126 Game Theory
______

Graduate (Spring)
Prereq: 14.122
Units: 3-0-9
______
Rigorous investigation of the evolutionary and epistemic foundations of solution concepts, such as rationalizability and Nash equilibrium. Covers classical topics, such as repeated games, bargaining, and supermodular games as well as new topics such as global games, heterogeneous priors, psychological games, and games without expected utility maximization. Applications provided when available.
D. Fudenberg, M. Yildiz

14.129 Advanced Contract Theory
______

Graduate (Spring); second half of term
Prereq: 14.121, 14.281, or permission of instructor
Units: 3-0-3
______
Recent developments in contract theory. Includes advanced models of moral hazard, adverse selection, mechanism design and incomplete contracts with applications to theory of the firm, organizational design, and financial structure.
Consult R. Townsend

14.13 Economics and Psychology
______

Undergrad (Fall) HASS Social Sciences ( HASS Elective )
Prereq: 14.01
Units: 4-0-8
Lecture: TR9-10.30 (E51-151) Recitation: F9 (E51-151) +final
______
Introduces the theoretical and empirical literature of behavioral economics. Examines important and systematic departures from the standard model in economics; covers intertemporal tradeoffs, risk preferences, social preferences, and intrinsic motivation; and applies theory to many different areas, such as credit card debt, addiction, portfolio choices, labor supply, and compensation policies of firms. Students review evidence from lab experiments, examine how the results can be integrated into models, and test models using field and lab data.
F. Schilbach
No textbook information available

14.137[J] Psychology and Economics
______

Graduate (Spring)
(Same subject as9.822[J])
Prereq: None
Units: 4-0-8
______
Examines "psychology appreciation" for economics students. Aims to enhance knowledge and intuition about psychological processes in areas relevant to economics. Increases understanding of psychology as an experimental discipline, with its own distinct rules and style of argument. Topics include self-knowledge, cognitive dissonance, self-deception, emotions, social norms, self-control, learning, mental accounting, memory, individual and group behavior, and some personality and psycho-analytic models. Within each of these topics, we showcase effective and central experiments and discuss their role in the development of psychological theory. Term paper required.
D. Prelec

14.147 Topics in Game Theory
______

Graduate (Spring)
Prereq: 14.126
Units: 4-0-8
______
Advanced subject on topics of current research interest.
J. Toikka, M. Yildiz

14.15[J] Networks
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Social Sciences
(Same subject as6.207[J])
Prereq: 6.041B or 14.30
Units: 4-0-8
______
Highlights common principles that permeate the functioning of diverse technological, economic and social networks. Utilizes three sets of tools for analyzing networks--random graph models, optimization, and game theory--to study informational and learning cascades; economic and financial networks; social influence networks; formation of social groups; communication networks and the Internet; consensus and gossiping; spread and control of epidemics; control and use of energy networks; and biological networks.
Consult Department Headquarters

14.16 Strategy and Information
______

Undergrad (Spring) HASS Social Sciences
Prereq: 14.01 or permission of instructor
Units: 4-0-8
______
Advanced course in game theory provides rigorous overview of equilibrium concepts for non-cooperative games in static and dynamic settings. Covers iterated strict dominance, rationalizability, Nash equilibrium, subgame perfection, sequential, perfect and proper equilibria, the intuitive criterion, and iterated weak dominance. Applications to auctions, bargaining, and repeated games. Introduces solution concepts for cooperative games and their non-cooperative implementations, as well as matching theory.
M. Manea

14.160 Behavioral Economics
______

Graduate (Fall)
Prereq: 14.122
Units: 4-0-8
Lecture: TR EVE (4.30-6 PM) (E51-390) Recitation: F4 (E51-361)
______
Covers recent theory and empirical evidence in behavioral economics. Topics include deviations from the neoclassical model in terms of (i) preferences (present bias, reference dependence, social preferences), (ii) beliefs (overconfidence, projection bias), and (iii) decision-making (cognition, attention, framing, persuasion), as well as (iv) market reactions to such deviations. Applications will cover a large range of fields, including labor and public economics, industrial organization, health economics, finance, and development economics.
A. Banerjee, F. Schilbach
No textbook information available

14.18 Mathematical Economic Modeling
(New)
______

Undergrad (Fall) HASS Social Sciences
Prereq: 14.04, 14.12, 14.15, or 14.19
Units: 4-0-8
Lecture: TR10.30-12 (E51-372) Recitation: F10 (E51-372)
______
Guides students through the process of developing and analyzing formal economic models and effectively communicating their results. Topics include decision theory, game theory, voting, and matching. Instruction and practice in oral and written communication provided. Prior coursework in microeconomic theory and/or proof-based mathematics required.
A. Wolitzky
No textbook information available

14.19 Market Design
______

Not offered academic year 2016-2017Undergrad (Spring) HASS Social Sciences
Prereq: 14.01
Units: 4-0-8
______
Covers the design and operation of organized markets, building on ideas from microeconomic and game theory. Topics may include mechanism design, auctions, matching markets, and other resource allocation problems.
Consult P. Pathak

14.191 Independent Research Paper
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units: 0-12-0
TBA.
______
Under supervision of a faculty member approved by Graduate Registration Officer, student writes a substantial, probably publishable research paper. Must be completed by the end of a student's second year to satisfy the departmental minor requirement.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

14.193 Advanced Seminar in Economics
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: 14.121, 14.451
Units arranged
14.193: Lecture: M12.30-2.30 (E52-314)
______
Reading and discussion of current topics in economics. Open to advanced graduate students by arrangement with individual members of the staff.
D. Fudenberg
14.193: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

14.195 Reading Seminar in Economics
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: 14.121
Units arranged [P/D/F]
14.195: TBA.
______
Reading and discussion of current topics in economics. Open to advanced graduate students by arrangement with individual members of the staff.
Staff
14.195: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

14.197 Independent Research
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Under supervision of a faculty member approved by Graduate Registration Officer, student conducts independent research.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

14.198, 14.199 Teaching Introductory Economics
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units: 2-0-2 [P/D/F]
14.198: TBA.
14.199: TBA.
______
Required of teaching assistants in introductory economics (14.01 and 14.02), under supervision of the faculty member in charge of the subject.
14.198:J. Gruber, J. Harris
14.199:R. Caballero, J. Poterba
14.198: No required or recommended textbooks
14.199: No required or recommended textbooks

Industrial Organization

14.20 Industrial Organization and Competitive Strategy
______

Undergrad (Spring) HASS Social Sciences
Prereq: 14.01
Units: 4-0-8
______
Analyzes the behavior and performance of firms in markets, with a particular focus on strategic interactions. Topics include monopoly power, behavior of firms in oligopoly markets, static and dynamic measurement of market performance, pricing and product choice decisions, advertising, research and development, and theory of the firm. Requires attendance and team participation in a Competitive Strategy Game.
N. Rose

14.21 Health Economics
______

Undergrad (Spring) HASS Social Sciences
Prereq: 14.01
Units: 3-0-9
URL: http://web.mit.edu/14.21j/www/
______
Applies theoretical and empirical tools of economics to problems of health and medical care delivery. Concentrates on selected topics such as decision-making under uncertainty, cost-benefit analysis, health insurance, physician remuneration, government regulation, health care systems of developing countries, and the economics of AIDS.
J. E. Harris

14.26 Economics of Incentives: Theory and Applications
______

Undergrad (Spring) HASS Social Sciences
Prereq: 14.01
Units: 4-0-8
______
Provides a rigorous, but not overly technical introduction to the economic theory of incentives and organization together with a varying set of applications. These include, among others, the optimal design of sales and CEO incentive schemes; the impact of incentives on risk taking and innovation; tournament design; the analysis of venture capital and other forms of financial incentive contracts; relational and behavioral aspects of incentive contracts; and various organizational design problems.
B. Holmstrom

14.27 Economics and E-Commerce
______

Undergrad (Fall) HASS Social Sciences
Prereq: 14.01; 6.041B or 14.30
Units: 4-0-8
URL: http://ocw.mit.edu/courses/economics/14-27-economics-and-e-commerce-fall-2014/
Lecture: MW10.30-12 (E51-372) Recitation: F11 (E51-361)
______
Uses theoretical economic models and empirical evidence to help understand the growth and future of e-commerce. Economic models help frame class discussions of, among other topics, content provision, privacy, piracy, sales taxation, group purchasing, price search, and advertising on the internet. Empirical project and paper required.
S. Ellison
No textbook information available

14.271 Industrial Organization I
______

Graduate (Fall)
Prereq: 14.04
Units: 5-0-7
Lecture: MW9-10.30 (E51-376) Recitation: F9-10.30 (E51-361) +final
______
Covers theoretical and empirical work dealing with the structure, behavior, and performance of firms and markets and core issues in antitrust. Topics include: the organization of the firm, monopoly, price discrimination, oligopoly, and auctions. Theoretical and empirical work are integrated in each area.
G. Ellison
Textbooks (Fall 2016)

14.272 Industrial Organization II
______

Graduate (Spring)
Prereq: 14.271
Units: 5-0-7
______
A continuation of 14.271. Topics covered include horizontal mergers and demand estimation, vertical integration and vertical restraints, natural monopoly and its regulation, public enterprise, political economy of regulation, network access pricing, deregulation of telecommunications, electric power, cable television, transportation sectors, and risk and environmental regulation.
N. Rose, M. Whinston

14.273 Advanced Topics in Industrial Organization
______

Graduate (Spring)
Prereq: 14.271
Units: 5-0-7
______
Empirical analysis of theoretically derived models of market behavior. Varied topics include demand estimation, differentiated products, production functions, analysis of market power, entry and exit, vertical relationships, auctions, matching markets, network externalities, dynamic oligopoly, moral hazard and adverse selection. Discussion will focus on methodological issues, including identification, estimation, counter-factual analysis and simulation techniques.
S. Ellison, W. Newey

14.281 Contract Economics
______

Graduate (Fall)
Prereq: 14.124
Units: 4-0-8
Lecture: MW10.30-12 (E51-361) Recitation: F12 (E51-372)
______
Covers theoretical research on contracts in static as well as dynamic settings. Emphasis is on canonical models in contracting (agency theory, mechanism design, incomplete contracting) illustrated by major areas of application (e.g. compensation, labor and capital markets, property rights, organizational design, corporate finance).
J. Toikka
No textbook information available

14.282 Introduction to Organizational Economics
______

Graduate (Fall)
Prereq: 14.124
Units: 5-0-7
Lecture: TR1-2.30 (E62-550) Recitation: F2.30-4 (E62-550) +final
______
Begins with survey of contract theory for organizational economists, then introduces the main areas of the field, including the boundary of the firm; decision-making, employment, structures and processes in organizations; and organizations other than firms.
R. Gibbons, J. Van Reenen, M. Whinston
No textbook information available

14.283 Advanced Topics in Organizational Economics I
______

Graduate (Spring); first half of term
Prereq: 14.282
Units: 2-0-4
______
Builds on the work done in 14.282 to develop more in-depth analysis of topics in the field.
R. Gibbons

14.284 Advanced Topics in Organizational Economics II
______

Graduate (Spring); second half of term
Prereq: 14.282
Units: 2-0-4
______
Builds on the work done in 14.282 to develop more in-depth analysis of topics in the field.
J. Van Reenen

Statistics and Econometrics

14.30 Introduction to Statistical Methods in Economics
______

Undergrad (Fall) Rest Elec in Sci & Tech
(Subject meets with14.300)
Prereq: Calculus II (GIR)
Units: 4-0-8
Lecture: TR1-2.30 (E51-057) Recitation: F2 (E51-145) +final
______
Self-contained introduction to probability and statistics with some economic applications. Elements of probability theory, sampling theory, statistical estimation, and hypothesis testing. Students taking graduate version complete additional assignments. May not count toward HASS requirement.
M. Manea
No textbook information available

14.300 Introduction to Statistical Methods in Economics
______

Graduate (Fall)
(Subject meets with14.30)
Prereq: Calculus II (GIR)
Units: 4-0-8
Lecture: TR1-2.30 (E51-057) Recitation: F2 (E51-145) +final
______
Self-contained introduction to probability and statistics with some economic applications. Elements of probability theory, sampling theory, statistical estimation, and hypothesis testing. Graduate students are expected to complete additional assignments.
M. Manea
No textbook information available

14.31 Data Analysis for Social Scientists
______

Undergrad (Spring) Institute Lab
(Subject meets with14.310)
Prereq: Calculus I (GIR)
Units: 4-0-8
______
Introduces methods for harnessing data to answer questions of cultural, social, economic, and policy interest. Presents essential notions of probability and statistics. Covers techniques in modern data analysis: regression and econometrics, prediction, design of experiment, randomized control trials (and A/B testing), machine learning, data visualization, analysis of network data, and geographic information systems. Projects include analysis of data with a written description and interpretation of results; may involve gathering of original data or use of existing data sets. Applications drawn from real world examples and frontier research. Instruction in use of the statistical package Stata. Students taking graduate version complete additional assignments.
D. Atkin, E. Duflo

14.310 Data Analysis for Social Scientists
______

Graduate (Spring)
(Subject meets with14.31)
Prereq: None
Units: 4-0-8
______
Introduces methods for harnessing data to answer questions of cultural, social, economic, and policy interest. Presents essential notions of probability and statistics. Covers techniques in modern data analysis: regression and econometrics, prediction, design of experiment, randomized control trials (and A/B testing), machine learning, data visualization, analysis of network data, and geographic information systems. Projects include analysis of data with a written description and interpretation of results; may involve gathering of original data or use of existing data sets. Applications drawn from real world examples and frontier research. Instruction in use of the statistical package Stata. Students taking graduate version complete additional assignments.
D. Atkin, E. Duflo

14.32 Econometrics
______

Undergrad (Fall)
Prereq: 14.30
Units: 4-0-8
Lecture: TR1-2.30 (E51-376) Recitation: F2 (E51-372) +final
______
Introduction to econometric ideas and methods, emphasizing data analysis for empirical causal inference. Topics include randomized trials, regression, instrumental variables, differences-in-differences, and regression discontinuity designs. Emphasizes applications and includes problem sets. May not count toward HASS requirement.
A. Mikusheva
Textbooks (Fall 2016)

14.33 Research and Communication in Economics: Topics, Methods, and Implementation
______

Undergrad (Fall, Spring) Institute Lab
Prereq: 14.01, 14.02, 14.32
Units: 3-4-5
Lecture: MW9-10.30 (E51-372) Lab: TBA
______
Exposes students to the process of conducting independent research in empirical economics and effectively communicating the results of the research. Emphasizes econometric analysis of an assigned economic question and culminates in each student choosing an original topic, performing appropriate analysis, and delivering oral and written project reports.
S. Ellison
No required or recommended textbooks

14.36 Advanced Econometrics
______

Undergrad (Spring)
(Subject meets with14.387)
Prereq: 14.32
Units: 4-0-8
______
Covers a range of topics including duration models, discrete choice models, differentiated product models, count models and other advanced models that are used in a wide variety of applications in applied microeconomics, financial economics, and business economics. Mastery of one or more techniques taught in class demonstrated through the completion of an econometrics paper.
J. Angrist, V. Chernozhukov

14.381 Statistical Method in Economics
______

Graduate (Fall)
Prereq: Calculus II (GIR), permission of instructor
Units: 5-0-7
Lecture: TR2.30-4 (E51-151) Recitation: F4-5.30 (E51-145) +final
______
Introduction to probability and statistics as background for advanced econometrics and introduction to the linear regression model. Covers elements of probability theory; sampling theory; asymptotic approximations; decision-theory approach to statistical estimation focusing on regression, hypothesis testing; and maximum-likelihood methods. Includes simple and multiple regression, estimation and hypothesis testing. Illustrations from economics and application of these concepts to economic problems. Enrollment limited.
I. Andrews, M. Kolesar
Textbooks (Fall 2016)

14.382 Econometrics
______

Graduate (Spring)
Prereq: 14.381 or permission of instructor
Units: 5-0-7
______
Regression analysis, focusing on departures from the standard Gauss-Markov assumptions, and simultaneous equations. Regression topics include heteroskedasticity, serial correlation, and errors in variables, generalized least squares, nonlinear regression, and limited dependent variable models. Covers identification and estimation of linear and nonlinear simultaneous equations models. Economic applications are discussed. Enrollment limited.
V. Chernozhukov

14.384 Time Series Analysis
______

Graduate (Fall)
Prereq: 14.382 or permission of instructor
Units: 5-0-7
Lecture: TR9-10.30 (E51-372) Recitation: W EVE (5.30-7 PM) (E51-361)
______
Studies theory and application of time series methods in econometrics, including spectral analysis, estimation with stationary and non-stationary processes, VARs, factor models, unit roots, cointegration, estimation of DSGE models, and Bayesian methods. Enrollment limited.
A. Mikusheva
Textbooks (Fall 2016)

14.385 Nonlinear Econometric Analysis
______

Graduate (Fall)
Prereq: 14.382 or permission of instructor
Units: 5-0-7
Lecture: MW1-2.30 (E51-057) Recitation: F1-2.30 (E51-361)
______
Studies micro-econometric models, including large sample theory for estimation and hypothesis testing, generalized method of moments, estimation of censored and truncated specifications, quantile regression, structural estimation, nonparametric and semiparametric estimation, panel data, bootstrapping, and simulation methods. Methods illustrated with economic applications. Enrollment limited.
A. Abadie, I. Andrews
Textbooks (Fall 2016)

14.386 New Econometric Methods
______

Graduate (Spring)
Prereq: 14.382
Units: 4-0-8
______
Focuses on recent developments in econometrics, especially structural estimation. Topics include nonseparable models, models of imperfect competition, auction models, duration models, and nonlinear panel data. Results illustrated with economic applications.
M. Kolesar

14.387 Applied Econometrics
______

Graduate (Spring)
(Subject meets with14.36)
Prereq: 14.382
Units: 4-0-8 [P/D/F]
______
Advanced treatment of core econometric ideas and methods. Emphasizes econometric theory and applications. Covers topics such as regression, instrumental variables, differences-in-differences, regression discontinuity designs, and problems related to standard errors and statistical inference. Includes problem sets with a theoretical and data-analytic component.
J. Angrist, V. Chernozhukov

14.389 Econometrics Paper
______

Graduate (IAP)
Prereq: 14.382 or 14.32
Units: 0-0-3
______
Paper in econometrics required of all PhD candidates. Paper due at the end of IAP.
A. Abadie

14.391 Workshop in Economic Research
______

Graduate (Fall) Can be repeated for credit
Prereq: 14.124, 14.454
Units: 2-0-10 [P/D/F]
Recitation: T EVE (4-6 PM) (E51-376) or M2.30-4 (E62-450) or M4-5.30 (E51-151) or R EVE (4-6 PM) (E53-482, E51-151) or M4-5.30 (E52-164) or T2.30-4 (HARVARD, E62-650) or W4-5.30 (E51-151) or R4-5.30 (E52-432)
______
No required or recommended textbooks

14.392 Workshop in Economic Research
______

Graduate (Spring) Can be repeated for credit
Prereq: 14.124, 14.454
Units: 2-0-10 [P/D/F]
______
Develops research ability of students through intensive discussion of dissertation research as it proceeds, individual or group research projects, and critical appraisal of current reported research. Workshops divided into various fields, depending on interest and size.
Staff

For additional related subjects in Statistics, see:

Civil and Environmental Engineering: 1.151, 1.155, 1.202J, 1.203J, 1.205J

Electrical Engineering and Computer Science: 6.041, 6.231, 6.245, 6.262, 6.431, 6.432, and 6.435

Management: 15.034, 15.061, 15.065, 15.070, 15.075, 15.076, 15.098, and 15.306

Mathematics: 18.05, 18.175, 18.177, 18.440, 18.441, 18.443, 18.445, 18.458, and 18.465

See also: 2.061, 2.830, 5.70, 5.72, 7.02, 8.044, 8.08, 10.816, 11.220, 11.221, 16.322, 17.872, 17.874, 22.38, HST.191, and MAS.622J.


left arrow|14.00-14.399 plus UROP|14.40-14.999 and UROP and Thesis|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 14: Economics
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Course 14: Economics
Fall 2016


National Income and Finance

14.41 Public Finance and Public Policy
______

Undergrad (Spring) HASS Social Sciences
(Subject meets with14.410)
Prereq: 14.01
Units: 4-0-8
Subject Cancelled Subject Cancelled
______
Explores the role of government in the economy, applying tools of basic microeconomics to answer important policy questions such as government response to global warming, school choice by K-12 students, Social Security versus private retirement savings accounts, government versus private health insurance, setting income tax rates for individuals and corporations. Students taking the graduate version complete additional assignments.
R. McKnight

14.410 Public Finance and Public Policy
(New)
______

Graduate (Spring)
(Subject meets with14.41)
Prereq: 14.01
Units: 4-0-8
Subject Cancelled Subject Cancelled
______
Explores the role of government in the economy, applying tools of basic microeconomics to answer important policy questions such as government response to global warming, school choice by K-12 students, Social Security versus private retirement savings accounts, government versus private health insurance, setting income tax rates for individuals and corporations. Students taking the graduate version complete additional assignments.
R. McKnight

14.416[J] Introduction to Financial Economics
______

Graduate (Fall)
(Same subject as15.416[J])
Prereq: 14.121, 14.122
Units: 4-0-8
Lecture: MW2.30-4 (E51-063) Recitation: F11 (E62-221)
______
Foundations of modern financial economics; individuals' consumption and portfolio decisions under uncertainty; valuation of financial securities. Topics include expected utility theory; stochastic dominance; mutual fund separation; portfolio frontiers; capital asset pricing model; arbitrage pricing theory; Arrow-Debreu economies; consumption and portfolio decisions; consumption beta models; spanning; options; market imperfections; no-trade theorems; rational expectations; financial signaling. Primarily for doctoral students in accounting, economics, and finance.
S. Ross
Textbooks (Fall 2016)

14.42 Environmental Policy and Economics
______

Undergrad (Spring) HASS Social Sciences
Prereq: 14.01
Units: 4-0-8
______
Investigates the proper role of government in the regulation of the environment. Presents tools necessary to estimate the costs and benefits of a variety of environmental policies. Focuses on both conceptual thinking and quantitative evaluation of environmental issues. Gives particular attention to climate change: defines the major concepts underlying the climate problem; examines the measurement of climate damages as well as the costs of mitigating them; and discusses the various policy options available to communities, countries, and international coalitions. Completion of 14.30 or equivalent statistics subject strongly recommended.
S. Stolper

14.43[J] Energy Decisions, Markets, and Policies
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject as11.161[J],15.031[J],17.397[J],21A.415[J])
Prereq: 14.01, 15.0111, or permission of instructor
Units: 4-0-8
______
Structured around choices and constraints regarding sources and uses of energy by households, firms, and governments, introduces managerial, economic, political, social and cultural frameworks for describing and explaining behavior at various levels of aggregation. Includes examples of cost-benefit, organizational and institutional analyses of energy generation, distribution, and consumption. Topics include the role of markets and prices; financial analysis of energy-related investments; institutional path dependence; economic and political determinants of government regulation and the impact of regulation on decisions; and other forms of government action and social norms regarding desired behavior and opportunities for businesses and consumers, including feedback into the political/regulatory system. Examples drawn from a wide range of countries and settings.
C. Warshaw

14.44[J] Energy Economics and Policy
______

Undergrad (Spring) HASS Social Sciences
(Same subject as15.037[J])
Prereq: 14.01
Units: 4-0-8
Credit cannot also be received for14.444,15.038
______
Analyzes business and public policy issues in energy markets and in the environmental markets to which they are closely tied. Examines the economic determinants of industry structure and evolution of competition among firms in these industries. Investigates successful and unsuccessful strategies for entering new markets and competing in existing markets. Industries studied include oil, natural gas, coal, electricity, and transportation. Topics include climate change and environmental policy, the role of speculation in energy markets, the political economy of energy policies, and market power and antitrust. Two team-based simulation games, representing the world oil market and a deregulated electricity market, act to cement the concepts covered in lecture. Students taking graduate version complete additional assignments. Limited to 60.
C. Knittel

14.440[J] Advanced Financial Economics I
______

Graduate (Spring)
(Same subject as15.440[J])
Prereq: 15.416
Units: 5-0-7
______
Covers advanced topics in the theory of financial markets with a focus on continuous time models. Topics include multiperiod securities markets and martingales; pricing of contingent securities such as options; optimal consumption and portfolio problems of an individual; dynamic equilibrium theory and the intertemporal capital asset pricing model; term structure of interest rates; and equilibrium with asymmetric information, transaction costs, and borrowing constraints. Primarily for doctoral students in finance, economics, and accounting.
H. Chen, L. Kogan

14.441[J] Advanced Financial Economics II
______

Graduate (Spring)
(Same subject as15.441[J])
Prereq: 14.121, 14.122, or 15.416J
Units: 3-0-9
______
Surveys selected topics in current advanced research in corporate finance. Theoretical and empirical analyses of corporate financing and investment decisions. Some background in information economics and game theory is useful. Primarily for doctoral students in accounting, economics, and finance.
Staff

14.442[J] Advanced Financial Economics III
______

Graduate (Fall)
(Same subject as15.442[J])
Prereq: 14.382, 15.416J, or permission of instructor
Units: 3-0-9
Lecture: TR2.30-4 (E62-687) Recitation: M EVE (6-7.30 PM) (E51-372)
______
Recent empirical methods in finance, including: the estimation and testing of market efficiency; the random walk hypothesis; the CAPM/APT; various term structure models; option pricing theories; and market microstructures; performance evaluation; bond rating and default analysis; event study methodology; continuous-time econometrics; and general time series methods. An empirical term project is required. Some econometric background and rudimentary computer programming skills are assumed. Primarily for doctoral students in finance, accounting, and economics.
Staff
Textbooks (Fall 2016)

14.444[J] Energy Economics and Policy
______

Graduate (Spring)
(Same subject as15.038[J])
Prereq: 14.01
Units: 4-0-8
Credit cannot also be received for14.44,15.037
______
Theoretical and empirical perspectives on individual and industrial demand for energy, energy supply, energy markets, and public policies affecting energy markets. Discusses aspects of the oil, natural gas, electricity, and nuclear power sectors. Examines energy tax, price regulation, deregulation, energy efficiency and policies for controlling pollution and CO2 emissions. Students taking the graduate version complete additional assignments. Limited to 60.
C. Knittel

14.451 Dynamic Optimization Methods with Applications
______

Graduate (Fall); first half of term
Prereq: 14.06, permission of instructor
Units: 3-0-3
Ends Oct 21. Lecture: TR1-2.30 (E51-151) Recitation: F2.30-4 (E51-151)
______
Provides an introduction to dynamic optimization methods, including discrete-time dynamic programming in non-stochastic and stochastic environments, and continuous time methods including the Pontryagin maximum principle. Applications may include the Ramsey model, irreversible investment models, and consumption choices under uncertainty. Enrollment limited.
A. Simsek
Textbooks (Fall 2016)

14.452 Economic Growth
______

Graduate (Fall); second half of term
Prereq: 14.451, permission of instructor
Units: 3-0-3
Begins Oct 24. Lecture: TR1-2.30 (E51-151) Recitation: F2.30-4 (E51-151) +final
______
Introduces the sources and modeling of economic growth and income differences across nations. Topics include an introduction to dynamic general equilibrium theory, the neoclassical growth model, overlapping generations, determinants of technological progress, endogenous growth models, measurement of technological progress, the role of human capital in economic growth, and growth in a global economy. Enrollment limited.
D. Acemoglu
No textbook information available

14.453 Economic Fluctuations
______

Graduate (Spring); first half of term
Prereq: 14.452, permission of instructor
Units: 3-0-3
______
Investigation of why aggregate economic activity fluctuates, and the role of policy in affecting fluctuations. Topics include the link between monetary policy and output, the economic cost of aggregate fluctuations, the costs and benefits of price stability, and the role of central banks. Introduction to real business cycle and new Keynesian models. Enrollment limited.
G. M. Angeletos

14.454 Economic Crises
______

Graduate (Spring); second half of term
Prereq: 14.453, permission of instructor
Units: 3-0-3
______
Introduction to current macroeconomic concerns with particular emphasis on medium-run economic fluctuations, economic crises, and the role of asset markets. Topics include the explanation of high chronic unemployment in some nations, the source of modern liquidity crises, the origin and end of speculative bubbles, and the factors that lead to substantial periods of economic stagnation. Enrollment limited.
R. Caballero

14.461 Advanced Macroeconomics I
______

Graduate (Fall)
Prereq: 14.122, 14.452
Units: 5-0-7
Lecture: TR1-2.30 (E51-361) Recitation: F2.30-4 (E51-361)
______
Advanced subject in macroeconomics that seeks to bring students to the research frontier. Topics vary from year to year, covering a wide spectrum of classical and recent research. Topics may include business cycles, optimal monetary and tax policy, monetary economics, banking, and financial constraints on investment and incomplete markets.
D. Acemolgu, I. Werning
No textbook information available

14.462 Advanced Macroeconomics II
______

Graduate (Spring)
Prereq: 14.461
Units: 5-0-7
______
Advanced topics on business cycles and crises; coordination problems; global games; DSGE models; financial frictions, micro founded macro models, analysis and design of financial systems.
J. Parker, R. Townsend

14.471 Public Economics I
______

Graduate (Fall)
Prereq: 14.04
Units: 4-0-8
Lecture: MW2.30-4 (E51-361) Recitation: F12 (E51-361)
______
Theory and evidence on government taxation policy. Topics include tax incidence; optimal tax theory; the effect of taxation on labor supply and savings; taxation and corporate behavior; and tax expenditure policy.
J. Poterba, I. Werning
No required or recommended textbooks

14.472 Public Economics II
______

Graduate (Spring)
Prereq: 14.471
Units: 3-0-9
______
Theory and evidence on government expenditure policy and on regulatory and tax responses to problems of market failure. Focuses on social insurance programs such as social security and unemployment insurance, and on the causes and consequences of rising health expenditures.
A. Finkelsein

14.473 Public Policy in Health Economics
______

Graduate (Spring)
Prereq: 14.122
Units: 4-0-8
______
Theory and evidence on the economics of the health care sector, with a particular emphasis on the economics of technological change and innovation.
H. Williams

International, Interregional, and Urban Economics

14.54 International Trade
______

Undergrad (Fall) HASS Social Sciences
Prereq: 14.01, 14.02
Units: 4-0-8
Lecture: MW10.30-12 (E51-057) Recitation: F11 (E52-164) +final
______
Introduction to the theory of international trade and finance with applications to current policy issues.
A. Costinot
Textbooks (Fall 2016)

14.581 International Economics I
______

Graduate (Fall)
Prereq: 14.04
Units: 5-0-7
Lecture: MW9-10.30 (E51-057) Recitation: W12 (E51-057)
______
Theory of international trade and foreign investment with applications in commercial policy.
D. Atkin, A. Costinot
Textbooks (Fall 2016)

14.582 International Economics II
______

Graduate (Spring)
Prereq: 14.06
Units: 5-0-7
______
Covers international capital flows, exchange rate fluctuations, global capital markets, emerging markets, crises, sovereign debt, international financial architecture, and bubbles.
A. Costinot

Labor Economics and Industrial Relations

14.64 Labor Economics and Public Policy
______

Not offered academic year 2017-2018Undergrad (Spring) HASS Social Sciences
Prereq: 14.30 or permission of instructor
Units: 4-0-8
______
Provides an introduction to the labor market, how it functions, and the important role it plays in people's lives world-wide. Topics include supply and demand, minimum wages, labor market effects of social insurance and welfare programs, the collective bargaining relationship, discrimination, human capital, and unemployment. Completion of or concurrent enrollment in 14.03 or 14.04 recommended.
J. Angrist

14.661 Labor Economics I
______

Graduate (Fall)
Prereq: 14.04, 14.32
Units: 5-0-7
Lecture: TR10.30-12 (E51-145) Recitation: F10.30-12 (E51-061) +final
______
A systematic development of the theory of labor supply, labor demand, and human capital. Topics include wage and employment determination, turnover, search, immigration, unemployment, equalizing differences, and institutions in the labor market. Particular emphasis on the interaction between theoretical and empirical modeling.
D. Acemoglu, J. Angrist
Textbooks (Fall 2016)

14.662 Labor Economics II
______

Graduate (Spring)
Prereq: 14.04, 14.32
Units: 5-0-7
______
Theory and evidence on the determinants of earnings levels, inequality, intergenerational mobility, skill demands, and employment structure. Particular focus on the determinants of worker- and firm-level productivity; and the roles played by supply, demand, institutions, technology and trade in the evolving distribution of income.
D. Autor, H. Williams

Economic History

14.70[J] Medieval Economic History in Comparative Perspective
______

Undergrad (Spring) HASS Social Sciences Communication Intensive HASS
(Same subject as21H.134[J])
Prereq: None
Units: 3-0-9
______
Surveys the conditions of material life and changing social and economic relations in medieval Europe using the comparative context of contemporary Islamic, Chinese, and Japanese experiences. Covers the emergence and decline of feudal institutions, the transformation of peasant agriculture, living standards and the course of epidemic disease, and the ebb and flow of long-distance trade across the Eurasian system. Particular emphasis placed on the study of those factors, both institutional and technological, which contributed to the emergence of capitalist organization and economic growth in western Europe in contrast to the trajectories followed by the other major medieval economies.
A. McCants

14.73 The Challenge of World Poverty
______

Undergrad (Fall) HASS Social Sciences Communication Intensive HASS
Prereq: None
Units: 4-0-8
Lecture: MW1-2.30 (E51-151) Recitation: F1 (E25-117, E51-085) or F2 (E25-117) +final
______
Designed for students who are interested in the challenge posed by massive and persistent world poverty. Examines extreme poverty over time to see if it is no longer a threat, why some countries grow fast and others fall further behind, if growth or foreign aid help the poor, what we can do about corruption, if markets or NGOs should be left to deal with poverty, where to intervene, and how to deal with the disease burden and improve schools.
E. Duflo, F. Schilbach
Textbooks (Fall 2016)

Economic Development

14.74 Foundations of Development Policy
______

Undergrad (Spring) HASS Social Sciences
(Subject meets with14.740)
Prereq: 14.01, 14.30
Units: 4-0-8
______

14.740 Foundations of Development Policy
______

Graduate (Spring)
(Subject meets with14.74)
Prereq: 14.01, 14.30
Units: 4-0-8
______
Explores the foundations of policy making in developing countries. Goal is to spell out various policy options and to quantify the trade-offs between them. Special emphasis on education, health, gender, fertility, adoption of technological innovation, and the markets for land, credit, and labor. Students taking the graduate version complete additional assignments.
D. Atkin, E. Duflo

14.75 Political Economy and Economic Development
______

Undergrad (Fall) HASS Social Sciences
Prereq: 14.01, 14.30
Units: 4-0-8
Lecture: MW2.30-4 (E51-372) Recitation: F3 (E51-372) +final
______
Explores the relationship between political institutions and economic development, covering key theoretical issues as well as recent empirical evidence. Topics include corruption, democracy, dictatorship, and war. Discusses not just what we know on these topics, but how we know it, covering how to craft a good empirical study or field experiment and how to discriminate between reliable and unreliable evidence.
B. Olken
Textbooks (Fall 2016)

14.770 Introduction to Collective Choice and Political Economy
______

Graduate (Fall)
Prereq: None
Units: 4-0-8
Lecture: TR10.30-12 (E52-532) Recitation: F12
______
Broad introduction to political economy. Covers topics from social choice theory to political agency models, including theories of voter turnout and comparison of political institutions.
A. Banerjee, C. Garcia-Jimeno
No textbook information available

14.771 Development Economics: Microeconomic Issues
______

Graduate (Fall)
Prereq: 14.121, 14.122
Units: 5-0-7
Lecture: MW10.30-12 (E52-432) Recitation: R4 (E51-393) +final
______
A rigorous introduction to core micro-economic issues in economic development, focusing on both key theoretical contributions and empirical applications to understand both why some countries are poor and on how markets function differently in poor economies. Topics include human capital (education and health); labor markets; credit markets; land markets; firms; and the role of the public sector.
E. Duflo, B. Olken
No textbook information available

14.772 Development Economics: Macroeconomics
______

Graduate (Spring)
Prereq: 14.121, 14.451
Units: 5-0-7
______
Dynamic models of growth and development emphasizing migration, modernization, risk and finance, and technological change; static and dynamic models of political economy; the dynamics of income distribution and institutional change; SME and larger firm structure in developing countries; development, transparency, and information systems; and functioning of financial markets and institutions in emerging markets, their design and regulation.
A. Banerjee, R. Townsend

14.773 Political Economy: Institutions and Development
______

Graduate (Spring)
Prereq: 14.121,14.451
Units: 5-0-7
______
Economists and policymakers increasingly realize the importance of political institutions in shaping economic performance, especially in the context of understanding economic development. Work on the determinants of economic policies and institutions is in its infancy, but is growing rapidly. Subject provides an introduction to this area. Topics covered: the economic role of institutions; the effects of social conflict and class conflict on economic development; political economic determinants of macro policies; political development; theories of income distribution and distributional conflict; the efficiency effects of distributional conflict; the causes and consequences of corruption; the role of colonial history; and others. Both theoretical and empirical approaches discussed. Subject can be taken either as part of the Development Economics or the Positive Political Economy fields.
D. Acemoglu, C. Garcia-Jimeno

14.781[J] Political Economy I: Theories of the State and the Economy
______

Graduate (Spring)
(Same subject as15.678[J],17.100[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Critical analysis of liberal, neoclassical, and Marxist perspectives on modern society. Alternative theories of economic growth, historical change, the state, classes, and ideology.
M. Piore, S. Berger

14.999 Topics in Inequality
______

Graduate (Spring)
Prereq: 14.452
Units: 2-0-4
______
Addresses empirical and theoretical issues of inequality from various perspectives, such as macroeconomic, labor, public finance, and political economy.
Consult D. Autor

14.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research and writing of thesis; to be arranged by the student with supervising committee.
Staff
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

14.THU Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 14.33
Units arranged
TBA.
______
Program of research and writing of thesis.
Staff
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

14.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 14.02
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

14.URG Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 14.02
Units arranged
TBA.
______
Participation in research with an individual faculty member or research group, independent research or study under the guidance of a faculty member. Admission by arrangement with individual faculty member.
Consult A. Mikusheva
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|14.00-14.399 plus UROP|14.40-14.999 and UROP and Thesis|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 15: Management
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Course 15: Management
Fall 2016


Managerial Economics

15.002 Sloan Innovation Period Requirement
______

Graduate (Fall, IAP, Spring, Summer)
Prereq: None
Units arranged [P/D/F]
TBA.
______
Units assigned to MBA students upon completion of the Sloan Innovation Period requirement. MBAs only.
Consult D. Gormley
No textbook information available

15.003 Analytics Tools
(New)
______

Graduate (Fall, IAP, Spring, Summer)
Prereq: None
Units: 2-0-1 [P/D/F]
TBA.
______
Units assigned to Master of Business Analytics students upon completion of the Analytics Tools requirement. Restricted to Master of Business Analytics students.
Consult D. Gormley
No textbook information available

15.010 Economic Analysis for Business Decisions
______

Graduate (Fall)
Prereq: None
Units: 4-0-5
Lecture: TR10-11.30 (E62-262, E51-315, E51-325) or TR8.30-10 (E62-262, E51-315, E51-325) Recitation: F12 (E51-345) or F1 (E62-250) or F12 (E51-395) or F1 (E51-395, E51-345) or F12 (E51-325) or F1 (E51-325) or F12 (E51-315) or F1 (E51-315) or F12 (E51-145) or F1 (E51-145) or F12 (E62-250) +final
______
Textbooks (Fall 2016)

15.011 Economic Analysis for Business Decisions
______

Graduate (Fall)
(Subject meets with15.0111)
Prereq: None
Units: 4-0-5
Lecture: TR1-2.30 (E51-335) Recitation: F12 (E51-151) or F1 (E51-151) +final
______
Introduces principles of microeconomics as a framework for making more informed managerial decisions and policy analysis. Includes the analysis of competitive markets with supply and demand, sources of market power and strategic pricing. Also provides an introduction to game theory to illustrate competition, anti-trust policy, and how to generate cooperation both within and between firms. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details. Intended for non-MBA students.
J. Doyle
Textbooks (Fall 2016)

15.0111 Economic Analysis for Business Decisions
______

Undergrad (Fall)
(Subject meets with15.011)
Prereq: None
Units: 4-0-5
Lecture: TR1-2.30 (E51-335) Recitation: F12 (E51-151) or F1 (E51-151) +final
______
Introduces principles of microeconomics as a framework for making more informed managerial decisions and policy analysis. Includes the analysis of competitive markets with supply and demand, sources of market power and strategic pricing. Also provides an introduction to game theory to illustrate competition, anti-trust policy, and how to generate cooperation both within and between firms. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. Doyle
Textbooks (Fall 2016)

15.012 Applied Macro- and International Economics
______

Graduate (Spring); first half of term
Prereq: None
Units: 4-0-2
______
Uses case studies to investigate the macroeconomic environment in which firms operate. Subject develops the basic tools of macro and international economics: monetary and fiscal policy, growth theory and exchange rates. Discusses recent emerging market and financial crises, examining their causes, how best to address them, and how to prevent them from recurring in the future. Evaluates different strategies of economic development, including an understanding of growth and development and the role of debt and foreign aid.
Staff

15.013 Industrial Economics for Strategic Decisions
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 15.010 or 15.011
Units: 3-0-9
______
Applies principles of industrial economics most relevant for corporate strategy to analysis of particular industries. Topics include market structure and its determinants; rational strategic behavior in small numbers situations; strategies for price and nonprice competition; dynamic pricing, output, and advertising decisions; entry and entry deterrence; competition with network externalities; investments under uncertainty; R&D and patent licensing; and the growth and evolution of industries.
R. Pindyck
No textbook information available

15.014 Applied Macro- and International Economics II
______

Graduate (Spring); second half of term
Prereq: 15.012 or 15.015
Units: 4-0-2
______
Establishes understanding of the development processes of societies and economies. Studies several dimensions of sustainability (environmental, social, political, institutional, economy, organizational, relational, and personal) and the balance among them. Explores the basics of governmental intervention, focusing on areas such as the judicial system, environment, social security, and health. Builds skills to determine what type of policy is most appropriate. Considers implications of new technologies on the financial sector: internationalization of currencies, mobile payment systems, and cryptocurrencies. Discusses the institutional framework to ensure choices are sustainable across all dimensions and applications.
R. Rigobon

15.015 Macro and International Economics
______

Graduate (Fall); first half of term
Prereq: Permission of instructor
Units: 2-0-4
Ends Oct 21. Lecture: TR8.30-10 (E51-395) or TR10-11.30 (E51-395)
______
Focuses on the policy and economic environment of firms. Subject divided in two parts: study of the closed economy and how monetary and fiscal policy interacts with employment, GNP, inflation, and interest rates; and study of the open economy with discussion of recent financial and currency crises in developed and emerging markets. Restricted to Sloan Fellows.
A. Cavallo
No required or recommended textbooks

15.021[J] Real Estate Economics
______

Graduate (Fall)
(Same subject as11.433[J])
Prereq: 14.01, 15.010, or 15.011
Units: 4-0-8
Lecture: TR11-12.30 (4-270) Recitation: M9-10.30 (9-354) +final
______
Develops understanding of the fundamental economic factors that shape the market for real property, as well as the influence of capital markets in asset pricing. Analyzes of housing as well as commercial real estate. Covers demographic analysis, regional growth, construction cycles, urban land markets, and location theory. Exercises and modeling techniques for measuring and predicting property demand, supply, vacancy, and prices.
W. C. Wheaton
Textbooks (Fall 2016)

15.023[J] Global Climate Change: Economics, Science, and Policy
______

Graduate (Spring)
(Same subject as12.848[J])
(Subject meets with12.348[J],15.026[J])
Prereq: Calculus II (GIR); 5.60; 14.01 or 15.010; or permission of instructor
Units: 3-0-6
______
Introduces scientific, economic, and ecological issues underlying the threat of global climate change, and the institutions engaged in negotiating an international response. Develops an integrated approach to analysis of climate change processes, and assessment of proposed policy measures, drawing on research and model development within the MIT Joint Program on the Science and Policy of Global Change. Graduate students are expected to explore the topic in greater depth through reading and individual research.
R. G. Prinn

15.024 Applied Economics for Managers
______

Graduate (Summer)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.722
______
Develops facility with concepts, language, and analytical tools of economics. Primary focus on microeconomics, analysis of markets and strategic interactions among firms. Emphasizes integration of theory, data, and judgment in the analysis of corporate decisions, and in the assessment of the changing global business environment. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
T. Stoker
No textbook information available

15.025 Game Theory for Strategic Advantage
______

Graduate (Spring)
(Subject meets with15.0251)
Prereq: 15.010, 15.011, 15.015, or 14.01
Units: 3-0-6
______
Develops and applies principles of game theory relevant to managers' strategic decisions. Topics include how to reason about strategies and opponents; strategic commitment, reputation, and "irrational" actions; brinkmanship and negotiation; auctions; and the design of markets and contests. Applications to a variety of business decisions that arise in different industries, both within and outside the firm. Meets with 15.0251 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
A. Bonatti

15.0251 Game Theory for Strategic Advantage
______

Undergrad (Spring)
(Subject meets with15.025)
Prereq: 15.0111 or 14.01
Units: 3-0-6
______
Develops and applies principles of game theory relevant to managers' strategic decisions. Topics include how to reason about strategies and opponents; strategic commitment, reputation, and "irrational" actions; brinkmanship and negotiation; auctions; and the design of markets and contests. Applications to a variety of business decisions that arise in different industries, both within and outside the firm. Meets with 15.025 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
A. Bonatti

15.026[J] Global Climate Change: Economics, Science, and Policy
______

Undergrad (Spring)
(Same subject as12.348[J])
(Subject meets with12.848[J],15.023[J])
Prereq: Calculus II (GIR); 5.60; 14.01 or 15.010; or permission of instructor
Units: 3-0-6
______
Introduces scientific, economic, and ecological issues underlying the threat of global climate change, and the institutions engaged in negotiating an international response. Develops an integrated approach to analysis of climate change processes, and assessment of proposed policy measures, drawing on research and model development within the MIT Joint Program on the Science and Policy of Global Change. Graduate students are expected to explore the topic in greater depth through reading and individual research. 12.340 recommended.
R. G. Prinn

15.031[J] Energy Decisions, Markets, and Policies
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject as11.161[J],14.43[J],17.397[J],21A.415[J])
Prereq: 14.01, 15.0111, or permission of instructor
Units: 4-0-8
______
Structured around choices and constraints regarding sources and uses of energy by households, firms, and governments, introduces managerial, economic, political, social and cultural frameworks for describing and explaining behavior at various levels of aggregation. Includes examples of cost-benefit, organizational and institutional analyses of energy generation, distribution, and consumption. Topics include the role of markets and prices; financial analysis of energy-related investments; institutional path dependence; economic and political determinants of government regulation and the impact of regulation on decisions; and other forms of government action and social norms regarding desired behavior and opportunities for businesses and consumers, including feedback into the political/regulatory system. Examples drawn from a wide range of countries and settings.
C. Warshaw

15.032[J] Engineering, Economics and Regulation of the Electric Power Sector
______

Graduate (Spring)
(Same subject as6.695[J],IDS.505[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Provides an in-depth and interdisciplinary look at electric power systems, focusing on regulation as the link among engineering, economic, legal, and environmental viewpoints. Topics include electricity markets, incentive regulation of network utilities, retail competition, tariff design, distributed generation, rural electrification, multinational electricity markets, environmental impacts, future of utilities and strategic sustainability issues under both traditional and competitive regulatory frameworks. Background in policy, microeconomics, or engineering desirable.
C. Vergara

15.034 Metrics for Managers
______

Graduate (Fall)
(Subject meets with15.0341)
Prereq: None
Units: 4-0-5
Lecture: TR2.30-4 (E51-335) Recitation: M2.30 (E51-149)
______
Enables students to evaluate the quality of evidence supported by data and to implement an empirical toolkit that provides credible answers to questions in finance, marketing, human resources, strategy, and general business planning. Uses econometrics as the underlying framework to develop deep understanding of regression modelling and its insights for data analytics using big and small data. Focuses primarily on empirical work conducted by students via in-class labs, problem sets, and projects. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. Doyle, R. Rigobon
No required or recommended textbooks

15.0341 Metrics for Managers
______

Undergrad (Fall)
(Subject meets with15.034)
Prereq: None
Units: 4-0-5
Lecture: TR2.30-4 (E51-335) Recitation: M2.30 (E51-149)
______
Enables students to evaluate the quality of evidence supported by data and to implement an empirical toolkit that provides credible answers to questions in finance, marketing, human resources, strategy, and general business planning. Uses econometrics as the underlying framework to develop deep understanding of regression modelling and its insights for data analytics using big and small data. Focuses primarily on empirical work conducted by students via in-class labs, problem sets, and projects. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. Doyle, R. Rigobon
No required or recommended textbooks

15.037[J] Energy Economics and Policy
______

Undergrad (Spring) HASS Social Sciences
(Same subject as14.44[J])
Prereq: 14.01
Units: 4-0-8
Credit cannot also be received for14.444,15.038
______
Analyzes business and public policy issues in energy markets and in the environmental markets to which they are closely tied. Examines the economic determinants of industry structure and evolution of competition among firms in these industries. Investigates successful and unsuccessful strategies for entering new markets and competing in existing markets. Industries studied include oil, natural gas, coal, electricity, and transportation. Topics include climate change and environmental policy, the role of speculation in energy markets, the political economy of energy policies, and market power and antitrust. Two team-based simulation games, representing the world oil market and a deregulated electricity market, act to cement the concepts covered in lecture. Students taking graduate version complete additional assignments. Limited to 60.
C. Knittel

15.038[J] Energy Economics and Policy
______

Graduate (Spring)
(Same subject as14.444[J])
Prereq: 14.01
Units: 4-0-8
Credit cannot also be received for14.44,15.037
______
Theoretical and empirical perspectives on individual and industrial demand for energy, energy supply, energy markets, and public policies affecting energy markets. Discusses aspects of the oil, natural gas, electricity, and nuclear power sectors. Examines energy tax, price regulation, deregulation, energy efficiency and policies for controlling pollution and CO2 emissions. Students taking the graduate version complete additional assignments. Limited to 60.
C. Knittel

15.040 Seminar in Managerial Economics
______

Graduate (Spring) Can be repeated for credit
Prereq: 15.010, 15.012
Units arranged
______
Group study of current topics related to managerial economics.
T. M. Stoker

Operations Research/Statistics

15.053 Optimization Methods in Business Analytics
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: None
Units: 4-0-8
______
Introduces optimization methods with a focus on modeling, solution techniques, and analysis. Covers linear programming, network optimization, integer programming, and nonlinear programming. Applications to logistics, manufacturing, data analysis, transportation, marketing, project management, and finance. Includes a project in which student teams select and solve an optimization problem (possibly a large-scale problem) of practical interest.
J. Orlin

15.054[J] The Airline Industry
______

Graduate (Fall)
(Same subject as1.232[J],16.71[J])
Prereq: None
Units: 3-0-9
Lecture: MW1-2.30 (35-225)
______
Overview of the global airline industry, focusing on recent industry performance, current issues and challenges for the future. Fundamentals of airline industry structure, airline economics, operations planning, safety, labor relations, airports and air traffic control, marketing, and competitive strategies, with an emphasis on the interrelationships among major industry stakeholders. Recent research findings of the MIT Global Airline Industry Program are showcased, including the impacts of congestion and delays, evolution of information technologies, changing human resource management practices, and competitive effects of new entrant airlines. Taught by faculty participants of the Global Airline Industry Program.
P. P. Belobaba, A. I. Barnett, C. Barnhart, R. J. Hansman, T. A. Kochan
Textbooks (Fall 2016)

15.060 Data, Models, and Decisions
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.730
Lecture: MW8.30-10 (E62-262, E51-335, E62-223) or MW10-11.30 (E62-262, E51-335, E62-223) Recitation: R4 (E62-233) or W3 (E52-164, E51-149, E62-233) or R3 (E62-233) or R1 (E62-276) +final
______
Introduces students to the basic tools in using data to make informed management decisions. Covers introductory probability, decision analysis, basic statistics, regression, simulation, linear and nonlinear optimization, and discrete optimization. Computer spreadsheet exercises, cases, and examples drawn from marketing, finance, operations management, and other management functions. Restricted to first-year Sloan master's students.
D. Bertsimas, R. Freund, G. Perakis, A. S. Schulz
No textbook information available (Summer 2016); Textbooks (Fall 2016)

15.062[J] Data Mining: Finding the Data and Models that Create Value
______

Graduate (Fall); second half of term
(Same subject asIDS.145[J])
(Subject meets with15.0621)
Prereq: 15.060 or 15.075
Units: 2-0-4
Begins Oct 31. Lecture: MW4-5.30 (E51-345) Recitation: T4 (E51-315)
______
Provides an introduction to data mining and machine learning, a class of methods that assist in recognizing patterns and making intelligent use of massive amounts of data collected via the internet, e-commerce, electronic banking, point-of-sale devices, bar-code readers, medical databases, search engines, and social networks. Includes topics in logistic regression, association rules, tree-structured classification and regression, cluster analysis, discriminant analysis, and neural network methods. Presents examples of successful applications in areas such as credit ratings, fraud detection, marketing, customer relationship management, and investments. Introduces data-mining software. Term project required. Meets with 15.0621 when offered concurrently. Students taking graduate version complete additional assignments.
R. E. Welsch
Textbooks (Fall 2016)

15.0621 Data Mining: Finding the Data and Models that Create Value
______

Undergrad (Fall); second half of term
(Subject meets with15.062[J],IDS.145[J])
Prereq: 15.075
Units: 2-0-4
Begins Oct 31. Lecture: MW4-5.30 (E51-345) Recitation: T4 (E51-315)
______
Provides an introduction to data mining and machine learning, a class of methods that assist in recognizing patterns and making intelligent use of massive amounts of data collected via the internet, e-commerce, electronic banking, point-of-sale devices, bar-code readers, medical databases, search engines, and social networks. Includes topics in logistic regression, association rules, tree-structured classification and regression, cluster analysis, discriminant analysis, and neural network methods. Presents examples of successful applications in areas such as credit ratings, fraud detection, marketing, customer relationship management, and investments. Introduces data-mining software. Term project required. Meets with 15.062 when offered concurrently. Students taking graduate version complete additional assignments.
R. E. Welsch
Textbooks (Fall 2016)

15.064[J] Engineering Probability and Statistics
______

Graduate (Summer)
(Same subject asIDS.210[J])
Prereq: Calculus II (GIR)
Units: 4-0-8
______
Modeling and analysis of uncertainty and variation. Covers probability models and distributions, regression, and basic statistical procedures pertinent to manufacturing and operations. Introduces experimental and robust design, statistical process control, forecasting, and data-mining. Students use a data analysis package, such as JMP, Minitab, or MATLAB. Primarily for Leaders for Global Operations students.
A. I. Barnett, R. E. Welsch
No textbook information available

15.066[J] System Optimization and Analysis for Operations
______

Graduate (Summer)
(Same subject as2.851[J])
Prereq: Calculus II (GIR)
Units: 4-0-8
______
Introduction to mathematical modeling, optimization, and simulation, as applied to manufacturing. Specific methods include linear programming, network flow problems, integer and nonlinear programming, discrete-event simulation, heuristics and computer applications for manufacturing processes and systems. Restricted to Leaders for Global Operations students.
V. Farias
No textbook information available

15.068 Statistical Consulting
______

Graduate (Fall, Spring)
Prereq: 15.060
Units: 3-0-6
Lecture: MW4-5.30 (E51-145)
______
Addresses statistical issues as a consultant would face them: deciphering the client's question; finding appropriate data; performing a viable analysis; and presenting the results in compelling ways. Real-life cases and examples.
A. I. Barnett
Textbooks (Fall 2016)

15.070[J] Advanced Stochastic Processes
______

Graduate (Spring)
(Same subject as6.265[J])
Prereq: 6.431B, 15.085J, 18.100A, 18.100B, or 18.100Q
Units: 3-0-9
______
Analysis and modeling of stochastic processes. Topics include measure theoretic probability, martingales, filtration, and stopping theorems; elements of large deviations theory; Brownian motion and reflected Brownian motion; stochastic integration and Ito calculus; functional limit theorems. Applications to finance theory, insurance, queueing and inventory models.
D. Gamarnik, G. Bresler

15.071 The Analytics Edge
______

Graduate (Spring)
(Subject meets with15.0711)
Prereq: 15.053 or 15.060
Units: 4-0-8
______
Presents real-world examples in which quantitative methods provide a significant competitive edge that has led to a first order impact on some of today's most important companies. Examples include finance (quantitative asset management and options pricing), sports, health care, revenue management, supply chains, and the Internet. Outlines the competitive landscape. Presents the key quantitative methods that created the edge (data-mining, dynamic optimization, simulation), and discusses their impact. Uses R programming language. Includes team projects. Meets with 15.0711 when offered concurrently. Students taking graduate version complete additional assignments.
D. Bertsimas

15.0711 The Analytics Edge
______

Undergrad (Spring)
(Subject meets with15.071)
Prereq: 15.053
Units: 4-0-8
______
Presents real-world examples in which quantitative methods provide a significant competitive edge that has led to a first order impact on some of today's most important companies. Examples include finance (quantitative asset management and options pricing), sports, health care, revenue management, supply chains, and the Internet. Outlines the competitive landscape. Presents the key quantitative methods that created the edge (data-mining, dynamic optimization, simulation), and discusses their impact. Uses R programming language. Includes team projects. Meets with 15.071 when offered concurrently. Students taking graduate version complete additional assignments.
D. Bertsimas

15.073[J] Logistical and Transportation Planning Methods
______

Graduate (Spring)
(Same subject as1.203[J],16.76[J])
Prereq: 6.041B
Units: 3-0-9
______
Quantitative techniques of operations research with emphasis on applications in transportation systems analysis (urban, air, ocean, highway, and pickup and delivery systems) and in the planning and design of logistically oriented urban service systems (e.g., fire and police departments, emergency medical services, and emergency repair services). Unified study of functions of random variables, geometrical probability, multi-server queuing theory, spatial location theory, network analysis and graph theory, and relevant methods of simulation. Computer exercises and discussions of implementation difficulties.
R. C. Larson, A. I. Barnett

15.074[J] Predictive Data Analytics and Statistical Modeling
______

Graduate (Spring)
(Same subject asIDS.213[J])
Prereq: 6.431, 15.060, or permission of instructor
Units: 4-0-5
Credit cannot also be received for15.0741
______
Provides a brief review of statistics and regression drawn from advanced topics, such as bootstrap resampling, variable selection, data and regression diagnostics, visualization, and Bayesian and robust methods. Covers data-mining and machine learning, including classification, logistic regression, and clustering. Culminates with time series analysis and forecasting, design of experiments, analysis of variance, and process control. Uses statistical computing systems based on application add-ins and stand-alone packages. Case studies involve finance, management science, consulting, risk management, and engineering systems. Term project required. Meets with 15.0741 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details
R. E. Welsch

15.0741 Predictive Data Analytics and Statistical Modeling
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 6.041B
Units: 4-0-5
Credit cannot also be received for15.074,IDS.213
______
Provides a brief review of statistics and regression drawn from advanced topics, such as bootstrap resampling, variable selection, data and regression diagnostics, visualization, and Bayesian and robust methods. Covers data-mining and machine learning, including classification, logistic regression, and clustering. Culminates with time series analysis and forecasting, design of experiments, analysis of variance, and process control. Uses statistical computing systems based on application add-ins and stand-alone packages. Case studies involve finance, management science, consulting, risk management, and engineering systems. Term project required. Meets with 15.074 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
R. E. Welsch

15.075[J] Statistical Thinking and Data Analysis
______

Undergrad (Spring) Institute Lab
(Same subject asIDS.013[J])
Prereq: 6.041B or 15.079
Units: 3-1-8
______
Introduces a rigorous treatment of statistical data analysis while helping students develop a strong intuition for the strengths and limitations of various methods. Topics include statistical sampling and uncertainty, estimation, hypothesis testing, linear regression, classification, analysis of variation, and elements of data mining. Involves empirical use of hypothesis testing and other statistical methodologies in several domains, including the assessment of A-B experiments on the web and the identification of genes correlated with diseases.
R. Mazumder

15.077[J] Statistical Learning and Data Mining
______

Graduate (Spring)
(Same subject asIDS.211[J])
Prereq: 6.431, 15.085, or 18.600; 18.06 or 18.700
Units: 4-0-8
______
Advanced introduction to the theory and application of statistics, data-mining, and machine learning, concentrating on techniques used in management science, marketing, finance, consulting, engineering systems, and bioinformatics. First half builds the statistical foundation for the second half, with topics selected from sampling, including the bootstrap, theory of estimation, testing, nonparametric statistics, analysis of variance, categorical data analysis, regression analysis, MCMC, EM, Gibbs sampling, and Bayesian methods. Second half focuses on data mining, supervised learning, and multivariate analysis. Topics selected from logistic regression; principal components and dimension reduction; discrimination and classification analysis, including trees (CART), partial least squares, nearest neighbors, regularized methods, support vector machines, boosting and bagging, clustering, independent component analysis, and nonparametric regression. Uses statistics software packages, such as R and MATLAB for data analysis and data mining. Includes a term project.
R. E. Welsch

15.079 Introduction to Applied Probability
______

Graduate (Fall)
(Subject meets with15.0791)
Prereq: Calculus I (GIR)
Units: 4-0-8
Lecture: MW1-2.30 (E51-372) +final
______
Presents probability from the perspective of applied mathematics, with strong emphasis on an intuitive overview of key theorems and continuing demonstrations of their usefulness. Covers the laws of probability and numerous important discrete and continuous random variables, both individually and in combination. Introduces simulation. Draws applications from economics, finance, engineering, marketing, public policy, operations management, and operations research. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
A. Barnett, R. Larson
Textbooks (Fall 2016)

15.0791 Introduction to Applied Probability
(New)
______

Undergrad (Fall) Rest Elec in Sci & Tech
(Subject meets with15.079)
Prereq: Calculus I (GIR)
Units: 4-0-8
Lecture: MW1-2.30 (E51-372) +final
______
Presents probability from the perspective of applied mathematics, with strong emphasis on an intuitive overview of key theorems and continuing demonstrations of their usefulness. Covers the laws of probability and numerous important discrete and continuous random variables, both individually and in combination. Introduces simulation. Draws applications from economics, finance, engineering, marketing, public policy, operations management, and operations research. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
A. Barnett, R. Larson
Textbooks (Fall 2016)

15.081[J] Introduction to Mathematical Programming
______

Graduate (Fall)
(Same subject as6.251[J])
Prereq: 18.06
Units: 4-0-8
Lecture: TR1-2.30 (32-155) Recitation: F10 (36-156) or F12 (32-144)
______
Introduction to linear optimization and its extensions emphasizing both methodology and the underlying mathematical structures and geometrical ideas. Covers classical theory of linear programming as well as some recent advances in the field. Topics: simplex method; duality theory; sensitivity analysis; network flow problems; decomposition; integer programming; interior point algorithms for linear programming; and introduction to combinatorial optimization and NP-completeness.
J. N. Tsitsiklis, D. Bertsimas
Textbooks (Fall 2016)

15.082 Network Optimization
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 15.081 or permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Doctoral-level subject on network models and algorithms. Emphasizes design and analysis of efficient algorithms for network flow models. Topics may vary from year to year.
J. Orlin

15.083[J] Integer Programming and Combinatorial Optimization
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as6.859[J])
Prereq: 15.081J or permission of instructor
Units: 4-0-8
______
In-depth treatment of the modern theory of integer programming and combinatorial optimization, emphasizing geometry, duality, and algorithms. Topics include formulating problems in integer variables, enhancement of formulations, ideal formulations, integer programming duality, linear and semidefinite relaxations, lattices and their applications, the geometry of integer programming, primal methods, cutting plane methods, connections with algebraic geometry, computational complexity, approximation algorithms, heuristic and enumerative algorithms, mixed integer programming and solutions of large-scale problems.
D. J. Bertsimas, A. S. Schulz

15.084[J] Nonlinear Optimization
______

Graduate (Spring)
(Same subject as6.252[J])
Prereq: 18.06; 18.100A, 18.100B, or 18.100C
Units: 4-0-8
______
Unified analytical and computational approach to nonlinear optimization problems. Unconstrained optimization methods include gradient, conjugate direction, Newton, sub-gradient and first-order methods. Constrained optimization methods include feasible directions, projection, interior point methods, and Lagrange multiplier methods. Convex analysis, Lagrangian relaxation, nondifferentiable optimization, and applications in integer programming. Comprehensive treatment of optimality conditions and Lagrange multipliers. Geometric approach to duality theory. Applications drawn from control, communications, power systems, and resource allocation problems.
R. M. Freund, D. P. Bertsekas, G. Perakis

15.085[J] Fundamentals of Probability
______

Graduate (Fall)
(Same subject as6.436[J])
Prereq: Calculus II (GIR)
Units: 4-0-8
Lecture: MW2.30-4 (E51-345) Recitation: F2 (66-144) +final
______
Introduction to probability theory. Probability spaces and measures. Discrete and continuous random variables. Conditioning and independence. Multivariate normal distribution. Abstract integration, expectation, and related convergence results. Moment generating and characteristic functions. Bernoulli and Poisson process. Finite-state Markov chains. Convergence notions and their relations. Limit theorems. Familiarity with elementary notions in probability and real analysis is desirable.
J. N. Tsitsiklis, D. Gamarnik
Textbooks (Fall 2016)

15.089 Analytics Capstone
(New)
______

Graduate (IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
______
Practical application of business analytics problems within a real company. Teams of 1-2 students, matched with company projects, visit companies to define project and scope. In class, students refine and improve on projects and devise methods for solving problems for their select companies. Mentors are assigned to each team. The culmination of the program is summer, on-site, practical training. Restricted to Master of Business Analytics students.
D. Bertsimas

15.093[J] Optimization Methods
______

Graduate (Fall)
(Same subject as6.255[J],IDS.200[J])
Prereq: 18.06
Units: 4-0-8
Lecture: TR2.30-4 (32-123) Recitation: W3 (66-168) or F1 (66-144) +final
______
Introduces the principal algorithms for linear, network, discrete, robust, nonlinear, dynamic optimization and optimal control. Emphasizes methodology and the underlying mathematical structures. Topics include the simplex method, network flow methods, branch and bound and cutting plane methods for discrete optimization, optimality conditions for nonlinear optimization, interior point methods for convex optimization, Newton's method, heuristic methods, and dynamic programming and optimal control methods.
D. Bertsimas, P. Parrilo
Textbooks (Fall 2016)

15.094[J] Robust Modeling, Optimization, and Computation
______

Graduate (Spring)
(Same subject as1.142[J])
Prereq: 18.06 or permission of instructor
Units: 4-0-8
______
Introduces modern robust optimization, including theory, applications, and computation. Presents formulations and their connection to probability, information and risk theory for conic optimization (linear, second-order, and semidefinite cones) and integer optimization. Application domains include analysis and optimization of stochastic networks, optimal mechanism design, network information theory, transportation, pattern classification, structural and engineering design, and financial engineering. Students formulate and solve a problem aligned with their interests in a final project.
D. Bertsimas

15.096 Prediction: Machine Learning and Statistics
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Gives a practical background and theoretical foundation to machine learning algorithms and Bayesian analysis. Includes an overview of the top ten algorithms in data mining. Covers frameworks for knowledge discovery, a unified view of support vector machines, AdaBoost and regression based on regularized risk minimization; generalization bounds from statistical learning theory based on covering numbers, VC dimension, and the margin theory; as well as basic Bayesian analysis and notes on the history of machine learning and statistics.
C. Rudin

15.097 Seminar in Statistics and Data Analysis
______

Graduate (Spring)
Prereq: Permission of instructor
Units arranged
______
Group study of current topics related to statistics and data analysis.
C. Rudin

15.098 Seminar in Applied Probability and Stochastic Processes
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: 6.431B
Units: 2-0-4
______
Doctoral student seminar covering current topics in applied probability and stochastic processes.
D. Gamarnik, D. Shah

15.099 Seminar in Operations Research
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 15.081J
Units arranged
Lecture: F10-12 (E62-550)
______
Doctoral student seminar covering current topics related to operations research.
D. Bertsimas, R. Freund, T. L. Magnanti, J. Orlin, G. Perakis, A. S. Schulz
No textbook information available

For additional related subjects in Statistics, see:

Civil and Environmental Engineering: 1.151, 1.155, 1.202, 1.203, and 1.205

Electrical Engineering and Computer Science: 6.041, 6.231, 6.245, 6.262, 6.431, and 6.435

Management: 15.034, 15.070, 15.075, and 15.098

Mathematics: 18.05, 18.175, 18.177, 18.440, 18.443, 18.445, and 18.465

See also: 2.830, 5.70, 5.72, 7.02, 8.044, 8.08, 10.816, 11.220, 16.322, 22.38, HST.191, and MAS.622

Health Care Management

15.122[J] Critical Reading and Technical Assessment of Biomedical Information
______

Graduate (Spring); first half of term
(Same subject asHST.977[J])
Prereq: SB degree in Biological Science or permission of instructor
Units: 1-0-2
______
Gain experience in critical reading of scientific literature, including patents, journal articles and FDA labels, with an emphasis on analyzing clinical controversies and emerging technologies in subject areas that have been or could become sources of entrepreneurial activity. Students required to analyze a variety of topics in the scientific literature, including screening for and cost-effectiveness of early detection of cancer, therapeutic opportunities in oncology, evaluation of immunotoxins and antibody therapies, and new prospects for the treatment of autoimmune disorders. To support the discussion of these topics, outside experts may be invited to participate as facilitators.
S. Lapidus, J. Karp

15.124[J] Evaluating a Biomedical Business Concept
______

Graduate (Fall)
(Same subject asHST.973[J])
Prereq: None
Units: 3-0-6
Lecture: W2.30-5.30 (E25-119)
______
Involves critical analysis of new biomedical business ideas. Inventors or principals of early stage companies present their ideas and provide background material including scientific papers and patents. Student teams interact with the companies, potential customers, other stakeholders and experts to develop a series of analyses concerning the critical issues. Company and student presentations supplemented by topic-specific lectures and presentations by biomedical entrepreneurs. Enrollment limited.
R. J. Cohen
Textbooks (Fall 2016)

15.128[J] Revolutionary Ventures: How to Invent and Deploy Transformative Technologies
______

Graduate (Fall)
(Same subject as9.455[J],20.454[J],MAS.883[J])
Prereq: Permission of instructor
Units: 2-0-7
URL: http://neuro.media.mit.edu/classes/neuroven/
Lecture: R2-4 (E15-341)
______
Seminar on envisioning and building ideas and organizations to accelerate engineering revolutions. Focuses on emerging technology domains, such as neurotechnology, imaging, cryotechnology, gerontechnology, and bio-and-nano fabrication. Draws on historical examples as well as live case studies of existing or emerging organizations, including labs, institutes, startups, and companies. Goals range from accelerating basic science to developing transformative products or therapeutics. Each class is devoted to a specific area, often with invited speakers, exploring issues from the deeply technical through the strategic. Individually or in small groups, students prototype new ventures aimed at inventing and deploying revolutionary technologies.
J. Bonsen, J. Jacobson
No textbook information available

15.132[J] Medicine for Managers and Entrepreneurs Proseminar
______

Graduate (Spring)
(Same subject asHST.972[J])
Prereq: None
Units: 3-0-6
______
Provides students with basic business-oriented clinical and technological knowledge related to health, healthcare and medicine through engagements with clinical and industry experts. Each session focuses on a specific field of medicine. Speakers include a basic science and/or clinical expert and a CEO or other senior executive involved in cutting-edge innovation in each area.
R. J. Cohen

15.136[J] Principles and Practice of Drug Development
______

Graduate (Fall)
(Same subject as7.547[J],10.547[J],HST.920[J],IDS.620[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://hst-hu-mit.mit.edu/courses/HST920
Lecture: W EVE (3-6 PM) (1-190)
______
Description and critical assessment of the major issues and stages of developing a pharmaceutical or biopharmaceutical. Drug discovery, preclinical development, clinical investigation, manufacturing and regulatory issues considered for small and large molecules. Economic and financial considerations of the drug development process. Multidisciplinary perspective from faculty in clinical; life; and management sciences; as well as industry guests.
T. J. Allen, C. L. Cooney, S. N. Finkelstein, A. J. Sinskey, G. K. Raju
No textbook information available

15.137[J] Case Studies and Strategies in Drug Discovery and Development
______

Graduate (Spring)
(Same subject as7.549[J],20.486[J],HST.916[J])
Prereq: None
Units: 2-0-4
______
Aims to develop appreciation for the stages of drug discovery and development, from target identification, to the submission of preclinical and clinical data to regulatory authorities for marketing approval. Following introductory lectures on the process of drug development, students working in small teams analyze how one of four new drugs or drug candidates traversed the discovery/development landscape. For each case, an outside expert from the sponsoring drug company or pivotal clinical trial principal investigator provides guidance and critiques the teams' presentations to the class.
S. R. Tannenbaum, A. J. Sinskey, A. W. Wood

15.141[J] Economics of the Health Care Industries
______

Graduate (Spring)
(Same subject asHST.918[J])
Prereq: Permission of instructor
Units: 3-0-6
______
Focuses on economic issues in various health care and allied industries, such as the pharmaceutical, biotechnology, medical device, vaccine and diagnostic sectors. Addresses differences between health care and other industries; regulatory issues, in the US and globally, that involve establishment of the efficacy and cost-effectiveness of treatments; managing those who manage research and development; policies to incentivize research and development for neglected tropical diseases; strategic issues in global pricing and marketing; use of e-commerce and information technology; personalized/stratified medicines and diagnostic biomarkers; and formation and management of various alliances. Visiting speakers from academia, government, NGOs, and industry. Assignments include 4 to 6 essays.
J. Doyle

Global Economics & Management

15.218 Global Economic Challenges and Opportunities
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
______
Analyzes the causes, effects and policy responses to major global economic issues. Focuses on financial crises, beginning with historical examples in emerging markets and building up to recent crises. Also focuses on current economic debates and challenges facing countries around the world. Possible topics include unsustainable debt, banking, European union, aging populations, inequality and poverty, oil and commodity markets, central bank policies, international institutions, and developments in emerging/emerged economies such as Brazil, Russia, India, and China. Some background in international economics recommended.
A. Orphanides

15.220 New Models for Global Business
______

Not offered academic year 2016-2017Graduate (Fall); second half of term
Prereq: None
Units: 3-0-3
______
Explores international dimensions of strategic management, and equips students to design strategies and structures that work effectively in an increasingly complex world economy. Focuses on a range of industries, from technology-based firms with global roots to emerging market multinationals. Topics include managing and leveraging big data, social and peer-to-peer networks, technology, and talent across national borders to develop capabilities and enhance competitive advantage. Includes a final group project in which students apply class concepts to evaluate strategic options for a startup or established global company of their choice. No final exam.
V. Karplus

15.221 Global Strategy and Organization
______

Graduate (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Focuses on the international dimensions of strategy and organization, and provides a framework for formulating strategies in an increasingly complex world economy, and for making those strategies work effectively. Topics include the globalization of industries, the continuing role of country factors in competition, organization of multinational enterprises, building global networks, and the changing managerial tasks under conditions of globalization. Restricted to Sloan Fellows in Innovation and Global Leadership.
Staff

15.223 Global Markets, National Policies and the Competitive Advantages of Firms
______

Graduate (Fall, Spring); second half of term
Prereq: None
Units: 3-0-3
Begins Oct 31. Lecture: TR10-11.30 (E51-149) or TR1-2.30 (E51-149)
______
Examines opportunities and risks firms face in today's global market. Provides conceptual tools for analyzing how governments and social institutions influence economic competition among firms embedded in different national settings. Public policies and institutions that shape competitive outcomes are examined through cases and analytical readings on different companies and industries operating in both developed and emerging markets. Restricted to Sloan Fellows in Innovation and Global Leadership.
S. Johnson
No textbook information available

15.225 Economy and Business in Modern China and India: China Lab and India Lab
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Provides an integrated approach to analyze the economies of China and India through action learning. The classroom portion covers macro issues of China and India, project-related issues and personal and learning reflections. The onsite portion involves working with a host company in China or in India. Students work in teams to tackle a real world business problem with an entrepreneurial Chinese or Indian company and produce a final deliverable for the host company. Students are required to take a mid semester trip during SIP and Spring Break to China or India to work onsite with the host company. Past lab projects have included creating a business plan for fundraising, developing a new market strategy, and crafting financial models; the projects have included both for-profit and NGO projects. Limited to graduate students who participate in China Lab or India Lab.
J. Grant, Y. Huang, M. Jester

15.227 - 15.229 Seminar in International Management
______

Graduate (Spring) Can be repeated for credit
Prereq: None
Units arranged
______
Group study of current topics related to international business.
Staff

15.232 Business Model Innovation: Global Health in Frontier Markets
______

Graduate (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Examines how new approaches to operations, revenue, marketing, finance, and strategy enable improved health care in resource-limited settings across Africa, Latin America, and Asia. Draws on system dynamics, design thinking, and strategic analysis. Explores success and failure in innovative healthcare delivery. Analysis of novel business models draws on case studies, videos, industry reports, research, and guest speakers. Students present their assessments of innovative base-of-the-pyramid health enterprises that aim to do more with less. Students who have not taken at least three management or business classes must apply to the instructor for permission to enroll before the first day of class.
A. Sastry

15.233 Global Health Lab
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Pairs faculty-mentored student teams with enterprises on the front lines of health care delivery in sub-Saharan Africa and South Asia. Custom-designed projects in strategy, business model innovation, operations, marketing, and technology designed to tackle specific barriers identified by each partnering organization. Interactive cases, practical exercises, and conversations with experts, all designed to support project work before, during, and after an intensive two-week onsite collaboration with entrepreneurs, leaders, staff, and stakeholders. Assignments include a portfolio of host deliverables, a foundational toolkit designed to support each project, and a distillation of learning from the field. Enrolled students must be available to work on site in Africa or South Asia for the entire weeks of SIP and Spring Break. Preference to students who have taken 15.232. Admission by application and interview in the prior November and December. Graduate students only.
A. Sastry

15.248 Israel Lab: Startup Nation's Entrepreneurship and Innovation Ecosystem
(New)
______

Graduate (Fall, IAP); second half of term
Prereq: None
Units: 3-0-6
Lecture: T EVE (4-7 PM) (E52-164)
______
Practical study of Israel's innovation and entrepreneurial ecosystem. On-campus component provides context about the country and its social and geopolitical issues; also introduces entrepreneurship lessons and team dynamics. During IAP, student teams work at the Israeli host organizations on complex problems in critical areas, such as high-tech, biotech, clean technology, and communications, with an emphasis on early stage ventures and their growth. Restricted to graduate students.
J. Cohen, C. Ortiz
No textbook information available

15.249 Institutions, Society, and International Business
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: None
Units arranged
______
Advanced seminar in the study of international management. Covers major theoretical work and approaches to empirical research in the fields of national business systems and globalization, linking them to the core frameworks of strategy and organization theory. Restricted to doctoral students.
E. Obukhova

History, Environment and Ethics

15.268 Choice Points: Readings on the Exercise of Power and Responsibility
______

Graduate (Spring)
Prereq: None
Units: 3-0-6 [P/D/F]
______
Managerial power and responsibility. Examines conflicts between power and moral responsibility and the contexts for choice in dealing with a number of such problems. Readings are principally "classics" used to illustrate several enduring issues. Restricted to Sloan Fellows in Innovation and Global Leadership.
Consult S. Sacca

15.269 Leadership Stories: Literature, Ethics, and Authority
______

Graduate (Fall)
Prereq: None
Units: 3-0-6
Lecture: MW2.30-4 (E51-315)
______
Explores how we use story to articulate ethical norms. The syllabus consists of short fiction, novels, plays, feature films and some non-fiction. Major topics include leadership and authority, professionalism, the nature of ethical standards, social enterprise, and questions of gender, cultural and individual identity, and work/life balance. Materials vary from year to year, but past readings have included work by Robert Bolt, Michael Frayn, Timothy Mo, Wole Soyinka, H.D. Thoreau, and others; films have included Crouching Tiger, Hidden Dragon, Hotel Rwanda, The Descendants, Motorcycle Diaries, Three Kings, and others. Draws on various professions and national cultures, and is run as a series of moderated discussions, with students centrally engaged in the teaching process.
L. Hafrey
Textbooks (Fall 2016)

Communication

15.270 Ethical Practice: Leading Through Professionalism, Social Responsibility, and System Design
______

Graduate (Spring); partial term
Prereq: None
Units: 3-0-3
______
Introduction to ethics in business, with a focus on business management. Students explore theoretical concepts in business ethics, and cases representing the challenges they will likely face as managers. Opportunity to work with guest faculty as well as business and other professional practitioners. Individual sessions take the form of moderated discussion, with occasional short lectures from instructor.
L. Hafrey

15.276 Communicating with Data
______

Undergrad (Spring)
Prereq: None
Units: 3-0-9
______
Focuses on how to communicate data clearly and effectively in a variety of situations. Develops skills to deliver data-oriented communications in both oral and written formats. Students participate in self-assessments and peer feedback. Final project involves a team presentation on a complex topic. Instruction in written and oral communication provided throughout course.
M. Kazakoff, B. Shields

15.277 Seminar in Communications
______

Graduate (Spring) Can be repeated for credit
Prereq: None
Units arranged
______

15.278 Seminar in Communications
______

Graduate (Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
______
Group study of current topics related to communication.
J. Yates

15.279 Management Communication for Undergraduates
______

Undergrad (Fall, Spring)
Prereq: None
Units: 3-0-9
Lecture: TR11.30-1 (E51-361)
______
Develops writing, speaking, teamwork, interpersonal, and cross-cultural communication skills necessary for management professionals. Assignments include creating persuasive memos, writing in response to cases, and giving presentations. Major project involves the production of a team report and presentation on a topic of interest to a professional audience.
L. Breslow
Textbooks (Fall 2016)

15.280 Communication for Leaders
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-1-5
Credit cannot also be received for15.710
Lecture: TR1-2.30 (E62-223) or TR4-5.30 (E51-145, E51-325) or TR1-2.30 (E51-325, E51-145) or TR2.30-4 (E51-145, E51-325) or TR1-2.30 (E51-372) or TR2.30-4 (E51-372, E62-223) or TR4-5.30 (E51-372, E62-223) Lab: TBA
______
Students develop and polish communication strategies and methods through discussion, examples, and practice. Emphasizes writing and speaking skills necessary for effective leaders. Includes several oral and written assignments which are integrated with other subjects, and with career development activities, when possible. Schedule and curriculum coordinated with Organizational Processes. Mandatory one hour recitation in small groups. Restricted to first-year Sloan graduate students.
N. Hartman, R. Pittore, V. Healy-Tangney, K. Blackburn, M. Kazakoff, J.Yates, B. Shields
Textbooks (Fall 2016)

15.281 Advanced Leadership Communication
______

Graduate (Spring)
Prereq: 15.279, 15.280, or permission of instructor
Units: 3-0-6
______
Introduces interactive oral and interpersonal communication skills critical to leaders, including strategies for presenting to a hostile audience, running effective and productive meetings, active listening, and contributing to group decision-making. Includes team-run classes on chosen communication topics, and an individual analysis of leadership qualities and characteristics. Students deliver an oral presentation and an executive summary, both aimed at a business audience.
N. Hartman, K. Blackburn, B. Shields, J. Yates, V. Healy-Tangney

15.282 EnActing Leadership: Shakespeare and Performance
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
______
Uses Shakespeare to challenge students' views of leadership and provide them with a deeper understanding of their performance as a leader. While performing shortened versions of Shakespeare's plays, students consider the serious questions they raise about the nature of leadership, power, and ambition, and explore their own leadership presence. Uses acting to strengthen speaking ability and personal presence.
C. Kelly

15.284 Strategic Leadership Communication
(New)
______

Graduate (Fall); partial term
Prereq: None
Units: 3-0-3
Lecture: MW10-11.30 (ENDS OCT 21) (E62-221) or MW1-2.30 (BEGINS OCT 31) (E51-361)
______
Introduces the essentials of how individuals and organizations develop and implement effective communication strategies, focusing on persuasion, audience analysis, communicator credibility, message construction, and delivery. Includes oral presentations and writing assignments with feedback to help students improve their communication effectiveness. Provides instruction to create communication strategies, develop and present clearly organized and powerful presentations, expand personal oral delivery and writing styles, and enhance presentations through effective visual aids. Restricted to Sloan Fellows.
N. Hartman, L. Breslow
Textbooks (Fall 2016)

15.289 Doctoral Seminar: Communication Skills for Academics
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-3
______
Focuses on the communication skills needed for a career in academia. Topics include writing for academic journals, preparing and delivering conference papers and job talks, peer reviewing for journals and conferences, and teaching. Participants are expected to work on a written project and deliver an oral presentation based on their current research. Limited to 20; priority to Sloan doctoral students who have completed their first year.
J. Yates, L. Breslow


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Produced: 29-SEP-2016 06:37 AMFall 2016 Course 15: Management
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Course 15: Management
Fall 2016


Work and Organizational Studies

15.301 Managerial Psychology Laboratory
______

Undergrad (Fall, Spring) Institute Lab
Prereq: None
Units: 3-3-9
Lecture: MW11 (32-155) Lab: F11 (E51-151) or F11 (E51-057)
______
Surveys individual and social psychology and organization theory interpreted in the context of the managerial environment. Laboratory involves projects of an applied nature in behavioral science. Emphasizes use of behavioral science research methods to test hypotheses concerning decision-making, group behavior, and organizational behavior. Instruction and practice in communication includes report writing, team projects, and oral and visual presentation. 12 units may be applied to the General Institute Laboratory Requirement. Shares lectures with 15.310.
Fall:J. Carroll
Spring:P. Osterman
Textbooks (Fall 2016)

15.305 Leadership and Management
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Subject Cancelled Subject Cancelled
______
Explores leadership from the military perspective taught by professors of military science from the Army, Navy and Air Force. Survey of basic principles for successfully managing and leading people, particularly in public service and the military. Develops skills in topics such as oral and written communication techniques, planning, team building, motivation, ethics, decision-making, and managing change. Relies heavily on interactive experiential classes with case studies, student presentations, role plays, and discussion. Also appropriate for non-management science majors.
Information: J. Camille, C. Prior

15.307 Leadership and Ethics
______

Graduate (Fall)
Prereq: None
Units: 2-0-0 [P/D/F]
Lecture: W4-5.30 (E62-250)
______
Foundations, pillars, principles and mantras of outstanding leadership introduced through in-class discussions and case studies presented by senior industry leaders (LGO and non-LGO alumni). Alumni also share their personal leadership experiences with the class. Leaders for Global Operations students only.
V. Erdekian
Textbooks (Fall 2016)

15.310 Managerial Psychology
______

Graduate (Fall, Spring)
Prereq: None
Units: 2-1-6
Lecture: MW11 (32-155) Recitation: F11 (E51-390, E51-372)
______
Surveys social psychology and organization theory as interpreted in the context of the managerial environment. Covers a number of diverse topics, including motivation and reward systems, social influence, groups and teams, leadership, power, organizational design and culture, and networks and communication patterns. Similar in content to 15.311; shares lectures with 15.301. Preference to non-Course 15 students.
Fall:J. Carroll
Spring:P. Osterman
Textbooks (Fall 2016)

15.311 Organizational Processes
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-3-4
Lecture: TR1-2.30 (E51-325) or TR2.30-4 (E51-325) or TR4-5.30 (E51-325, E62-223) or TR1-2.30 (E62-223) or TR2.30-4 (E62-223)
______
Enhances students' ability to take effective action in complex organizational settings by providing the analytic tools needed to analyze, manage, and lead the organizations of the future. Emphasizes the importance of the organizational context in influencing which individual styles and skills are effective. Employs a wide variety of learning tools, from experiential learning to the more conventional discussion of written cases. Centers on three complementary perspectives on organizations: the strategic design, political, and cultural "lenses" on organizations. Major team project to analyze an actual organizational change, with oral and written reports. Restricted to first-year Sloan master's students.
K. Kellogg, E. Apfelbaum, C. Turco
No required or recommended textbooks

15.312 Organizational Processes for Business Analytics
(New)
______

Undergrad (Fall)
Prereq: None
Units: 3-0-9
Lecture: TR2.30-4 (E62-221)
______
Develops appreciation for organizational dynamics and competence in navigating social networks, working in a team, demystifying rewards and incentives, leveraging the crowd, understanding change initiatives, and making sound decisions. Provides instruction and practice in written and oral communication through presentations, and interpersonal and group exercises.
R. Reagans, L. Breslow
No textbook information available

15.316 Building and Leading Effective Teams
______

Graduate (Summer)
Prereq: None
Units: 2-1-0 [P/D/F]
______
An intensive one-week introduction to leadership, teams, and learning communities. Introduction of concepts and use of a variety of experiential exercises to develop individual and team skills and develop supportive relationships within the Fellows class. Restricted to first-year Leaders for Global Operations students.
Consult J. S. Carroll
No textbook information available

15.317 Leadership and Organizational Change
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Course spans the entire two-year Leaders for Global Operations (LGO) program, with a focus on leadership that blends theory and practice. During their first summer in the program, students reflect on exemplary leaders' stories in cases, the arts, journalism, philosophy, and social science, and evaluate their own previous leadership experience. During the succeeding four semesters, they apply the lessons they have learned in class to their off-campus internship and other activities at Sloan, and intensively review that experience as they reach the end of the program. Classes take the form of moderated discussion, with the expectation that students will participate fully in each session; students also submit short, written deliverables throughout the program.
L. Hafrey
Textbooks (Summer 2016); No textbook information available (Fall 2016)

15.318 Discovering Your Leadership Signature
______

Graduate (Fall) Can be repeated for credit
Prereq: 15.311, 15.322, or permission of instructor
Units: 3-0-6
Credit cannot also be received for15.739
Lecture: TR10-11.30 (E62-221)
______
Provides the tools to better understand one's unique way of leading change, i.e. leadership signature. Involves intensive self-assessment and interactive exercises aimed to help students identify their key strengths and weaknesses and hone their leadership skills. Focuses on the individual leadership credo and techniques for building confidence and credibility. Students explore alternative approaches to leadership, compare and contrast various leadership styles, and look at a range of leadership capabilities.
D. Ancona
No required or recommended textbooks

15.320 Strategic Organizational Design
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
______
Focuses on effective organizational design in both traditional and innovative organizations, with special emphasis on innovative organizational forms that can provide strategic advantage. Topics include when to use functional, divisional, or matrix organizations; how IT creates new organizational possibilities; examples of innovative organizational possibilities, such as democratic decision-making, crowd-based organizations, internal resource markets, and other forms of collective intelligence. Team projects include inventing new possibilities for real organizations.
T. Malone

15.321 Improvisational Leadership: In-the-Moment Leadership Skills
______

Graduate (Fall, Spring); second half of term
Prereq: None
Units: 3-0-3
Begins Oct 31. Lecture: T EVE (4-7 PM) (E62-233)
______
Designed to provide a practical understanding of the skills of improvisation and their application to leadership. Examines the essential elements of successful leadership, including creativity, emotional intelligence, adaptability, and the capacity to develop effective influence strategies and build strong teams. Cultivates students' ability to respond to the unexpected with confidence and agility. Each class offers a highly experiential learning laboratory where students practice a wide variety of improvised business scenarios, interactive exercises, and simulations.
D. Giardella
Textbooks (Fall 2016)

15.322 Leading Organizations
______

Graduate (Fall); first half of term
Prereq: None
Units: 3-0-3 [P/D/F]
Credit cannot also be received for15.716
Ends Oct 21. Lecture: F8-12 (E51-335) or F1-5 (E51-335) Lab: F8-12 (E51-376) or F8-12 (E51-393) or F1-5 (E51-393) or F1-5 (E51-385) or F1-5 (E51-376) or F8-12 (E51-385) Recitation: F9.30-11.30 (E51-063) or F2.30-4.30 (E51-057) or F9.30-11.30 (E51-085) or F2.30-4.30 (E51-061, E51-390, E51-063)
______
Analyzes through lectures, discussions, and class exercises, the human processes underlying organizational behavior. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
J. Van Maanen
No textbook information available (Summer 2016); Textbooks (Fall 2016)

15.323 Leading from the Middle
______

Graduate (Spring); second half of term
Prereq: None
Units: 2-0-1 [P/D/F]
______
Students and Leaders for Global Operations (LGO) alumni develop and present case studies that focus on the challenges and opportunities of leading from positions in the middle of an organization. Restricted to Leaders for Global Operations program students.
L. Hafrey

15.324 Practical leadership
______

Graduate (Spring); second half of term
Prereq: None
Units: 3-0-3 [P/D/F]
______
Strengthens leadership capacities through feedback, reflection, and practice. Students use readings, role plays, experiential exercises, self-reflection, and reviews of their own videos, as well as focused coaching and feedback, to optimize their own leadership capabilities. Focuses on individual leadership growth. Culminates with submission of a written summary of students', reflections and experiences around leadership from throughout the term.
P. Bentley

15.325 Seminar in Leadership I
______

Graduate (Fall); second half of term
Prereq: None
Units: 2-0-1 [P/D/F]
Begins Oct 31. Lecture: M EVE (5.30-7 PM) (E51-325) or W EVE (5.30-7 PM) (E51-325)
______
Provides students opportunities to meet senior executives of private and public institutions, and discuss key management issues from the perspective of top management. Students prepare detailed briefings identifying and analyzing important management issues facing these organizations. Seminar includes a one week field trip to a domestic location. Restricted to MIT Sloan Fellows.
Consult S. Sacca
No textbook information available

15.326 Seminar in Leadership II
______

Graduate (Spring)
Prereq: 15.325
Units: 2-0-1 [P/D/F]
______
Continuation of subject 15.325 on the identification and analysis of important management issues. Students prepare briefings and meet with senior government and international leaders during field trips in selected international areas. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
S. Sacca

15.328 Seminar in Organizational Studies
______

Graduate (Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
______
No textbook information available

15.329 Seminar in Organizational Studies
______

Graduate (Spring) Can be repeated for credit
Prereq: None
Units arranged
______
Group study of current topics related to organizational studies.
Consult D. G. Ancona

15.339 Distributed Leadership Workshop
______

Graduate (IAP)
Prereq: None
Units: 2-0-4 [P/D/F]
______
Focuses on the key leadership capabilities needed in today's increasingly decentralized organizations: sense-making, relating, visioning, and inventing. Through conceptual discussions, small group exercises, and self-reflection, helps students understand leadership capabilities, evaluate their leadership strengths and weaknesses, articulate their values and aspirations, and practice developing leadership skills in interaction with class members.
D. Ancona, T. Malone, W. Orlikowski

15.341 Individuals, Groups, and Organizations
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Covers classic and contemporary theories and research related to individuals, groups, and organizations. Designed primarily for doctoral students in the Sloan School of Management who wish to familiarize themselves with research by psychologists, sociologists, and management scholars in the area commonly known as micro organizational behavior. Topics may include motivation, decision making, negotiation, power, influence, group dynamics, and leadership.
J. Curhan

15.342 Organizations and Environments
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: R8.30-11.30 (E62-446)
______
Provides an introduction to research in "organizations and environments," an interdisciplinary domain of inquiry drawing primarily from sociology, and secondarily from economics, psychology, and political science. Seeks to understand organizational processes and outcomes in the surrounding economic, cultural, and institutional context in which they are situated. Also provides an introduction to the main groups that together form the Behavioral Policy Sciences (BPS) area of MIT/Sloan, including economic sociology, organization studies, work and employment, strategic management, global management, and technology, innovation, and entrepreneurship. Consists of four modules taught by faculty from each of the four BPS groups, as well as integrative sessions taught by the main instructor. Preference to first-year doctoral students in BPS.
R. Reagans
No textbook information available

15.345 Doctoral Proseminar in Behavioral and Policy Sciences
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
______
A professional seminar for doctoral students to report on their research, work on their thesis proposals, and practice their job talks. Also addresses general professional issues such as publishing, searching for jobs, the academic career, etc.
J. Carroll

15.347 Doctoral Seminar in Research Methods I
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces the process of social research, emphasizing the conceptualization of research choices to ensure validity, relevance, and discovery. Includes research design and techniques of data collection as well as issues in the understanding, analysis, and interpretation of data.
M. Amengual

15.348 Doctoral Seminar in Research Methods II
______

Graduate (Fall)
Prereq: 15.347 or permission of instructor
Units: 3-0-6
Lecture: M EVE (3-6 PM) (E62-350)
______
Builds on 15.347 to examine contemporary social research methods in depth. Focuses on making students familiar with the most important quantitative methods (e.g., logit/probit models, models for ordinal and nominal outcomes, count models, event history models).
E. J. Castilla
Textbooks (Fall 2016)

Technology, Innovation and Entrepreneurship

15.350 Managing Technological Innovation and Entrepreneurship
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
______
Focuses on the challenges inherent in attempting to take advantage of both incremental innovation and more radical or breakthrough changes in products, processes and services. Highlights the importance of innovation to both new ventures and to large established firms and explores the organizational, economic and strategic problems that must be tackled to ensure innovation is a long term source of competitive advantage. Discussions and class presentations cover non- technical as well as technology-based innovation. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
Staff

15.356 Product and Service Development in the Internet Age
______

Graduate (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Traditional "in-house" innovation processes must be changed to benefit from emerging open-source innovation practices. Users are now increasingly developing their own b-to-b and b-to-c products. Course explains proven open innovation development methods such as crowdsourcing, innovation toolkits, tournaments and more. Includes visits from industry experts who present cases that illustrate the art required to implement each method.
E. A. von Hippel

15.357 Economics of Ideas, Innovation and Entrepreneurship
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: None
Units: 3-0-6
______
Advanced subject in the economics of technological change. Covers the micro-foundations of the knowledge production function (including the role of creativity and the impact of Science), the impact of institutions and strategic interaction on the commercialization of new technology, and the diffusion and welfare impact of ideas and technology. Includes a mixture and explicit comparisons of both theoretical and empirical research. Students should have adequate preparation in microeconomic theory and econometrics. Primarily for PhD students.
P. Azoulay, S. Stern

15.358 Software and Internet Entrepreneurship
______

Graduate (Spring)
Prereq: 15.900 or 15.902
Units: 3-0-6
______
Considers key strategic concepts, especially the distinction between being a product versus a services company, as well as a product versus a platform strategy. Reviews how software became a business (from early developments in services to the emergence of standardized products), and the transition to software as a service, and cloud computing. Studies critical techniques for managing sales and marketing, as well as product development and project management for software products. Examines how the business differs for various platforms - including new and traditional enterprise software, social media, internet video, and mobile competitors - as well as for entrepreneurs competing in these markets. Student teams help teach some weekly sessions and analyze emerging companies and sectors in team projects.
M. A. Cusumano, I. Sayeed

15.359[J] Innovation Engineering: Moving Ideas to Impact
(New)
______

Undergrad (Fall)
(Same subject as6.901[J])
Prereq: None
Units: 3-3-6
Lecture: TR9-10.30 (1-390)
______
Designed for students to gain the perspective of a Chief Technology Officer of a start-up, large corporation, or a not-for-profit. Details the innovation process, from an idea's inception through impact in the economy, regardless of organizational setting. Explores how solutions are developed to become ready for broader market deployment. Includes testing and development of the problem-solution fit, probing of solutions for robustness, and testing of both technical and operational scaling of proposed solutions. Examines the human aspects of innovation, specifically issues of team building and readiness. Considers the broader system for innovation, including the role of key stakeholders in shaping its success in order to arrive at an impactful solution. Addresses intellectual property, the effect of regulations and social and cultural differences across varied global markets, and the personal skillset necessary to align and manage these issues.
V. Bulovic, F. Murray
No textbook information available

15.360 Introduction to Technological Entrepreneurship
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-0-1
Lecture: W EVE (4-7 PM) (E62-233)
______
Provides an overview of entrepreneurial theory and practice for founding, developing and growing new enterprises, primarily but not exclusively focused on companies with a technological base. Weekly lectures and dinner discussion sessions by academic and practitioner faculty engaged in the MIT Entrepreneurship Program, supplemented by leaders of related MIT entrepreneurship activities, e.g., Trust Center for MIT Entrepreneurship, Technology Licensing Office, Deshpande Center, and Venture Mentoring Service, as well as successful entrepreneurs and venture capitalists. Includes student Open Mic presentations and discussion of new business ideas. Enrollment in ES.580, Silicon Valley Study Tour, for the following spring term required. No listeners; restricted to students in Sloan Entrepreneurship and Innovation (E&I) MBA track.
E. Roberts
No required or recommended textbooks

15.363[J] Strategic Decision Making in the Life Sciences
______

Graduate (Spring)
(Same subject asHST.971[J])
Prereq: None
Units: 3-0-6
______
Surveys key strategic decisions faced by managers, investors and scientists at each stage in the value chain of the life science industry. Aims to develop students' ability to understand and effectively assess these strategic challenges. Focuses on the biotech sector, with additional examples from the pharmaceutical and medical device sectors. Includes case studies, analytical models, and detailed quantitative analysis. Intended for students interested in building a life science company or working in the sector as a manager, consultant, analyst, or investor. Provides analytical background to the industry for biological and biomedical scientists, engineers and physicians with an interest in understanding the commercial dynamics of the life sciences or the commercial potential of their research.
J. Fleming, A. Zarur

15.364 Regional Entrepreneurship Acceleration Lab (REAL)
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.3641
______
Aimed at students seeking a research-based but action-oriented understanding of innovation ecosystems, such as Silicon Valley, Kendall Square/Massachusetts, and other sites across the globe. Provides a framework for analyzing these critical innovation economies. Outlines the design and delivery of policies and programs (e.g., accelerators, prizes, tax policy, immigration policy) intended to accelerate innovation-driven entrepreneurship. Takes a stakeholder perspective to examine the role of entrepreneurs, risk capital providers, large corporations, governments and universities in innovation-driven entrepreneurship. Meets with 15.364 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
P. Budden, F. Murray

15.3641 Regional Entrepreneurship Acceleration Lab (REAL)
(New)
______

Undergrad (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.364
______
Aimed at students seeking a research-based but action-oriented understanding of innovation ecosystems, such as Silicon Valley, Kendall Square/Massachusetts, and other sites across the globe. Provides a framework for analyzing these critical innovation economies. Outlines the design and delivery of policies and programs (e.g., accelerators, prizes, tax policy, immigration policy) intended to accelerate innovation-driven entrepreneurship. Takes a stakeholder perspective to examine the role of entrepreneurs, risk capital providers, large corporations, governments and universities in innovation-driven entrepreneurship. Meets with 15.364 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
P. Budden, F. Murray

15.366 Energy Ventures
______

Graduate (Fall)
Prereq: 15.910; 15.390 or 15.371; 10.391 or 10.579
Units: 3-0-9
Lecture: R EVE (5-8 PM) (32-124) Recitation: F10.30-12 (E40-160)
______
Project-based approach to innovation and venture creation in the energy sector. Explores how innovation and entrepreneurial concepts apply (or do not apply) to the significant opportunities in the industry. Working in teams, students create new ventures specifically for the energy sector. Lectures guide teams through key elements of their projects. Concurrent enrollment in 15.933 recommended.
W. Aulet, T. Hynes, F. O'Sullivan
No textbook information available

15.367[J] Healthcare Ventures
______

Graduate (Spring)
(Same subject asHST.978[J])
Prereq: 15.910; 15.390 or 10.391 or 10.579
Units: 3-0-9
______
Focuses on entrepreneurship, with emphasis on startups bridging digital health and high-tech. Explores US and global macro trends and case studies. Features lectures by leading healthcare entrepreneurs and venture investors, and provides practical experience in networking through team projects. Evaluation based on team participation and assignments, including two team presentations. Video conference facilities provided to facilitate remote participation by Executive MBA and traveling students. Enrollment by application only. Enrollment by application only
M. Gray, Z. Chu

15.369 Seminar in Corporate Entrepreneurship
______

Not offered academic year 2016-2017Graduate (Fall); partial term
Prereq: 15.310 or 15.311
Units: 3-0-3
Subject Cancelled Subject Cancelled
______
Addresses the practical challenges of making an established company entrepreneurial and examines various roles related to corporate entrepreneurship. Outside speakers complement faculty lectures. Topics may vary from term to term.
A. Kacperczyk, C. Kiefer

15.371[J] Innovation Teams
______

Graduate (Fall, Spring)
(Same subject as 10.807[J])
Prereq: 15.911 or permission of instructor
Units: 4-4-4
Lecture: W11-2 (32-144) Lab: F9-11.30 (32-155)
______
Students work in teams to develop commercialization strategies for innovative research projects generated in MIT laboratories. Projects cover critical aspects of commercialization, from selecting the target application and market for the technology to developing an intellectual property strategy and performing a competitive analysis. Instruction provided in communication and teamwork skills, as well as analysis of the challenges and benefits of technology transfer. Includes lectures, guest speakers, and extensive team coaching. Designed primarily for students in engineering, science, and management. Applications, resumes, and a brief statement of interest are required prior to registration.
F. Murray, L. Perez-Breva, N. Afeyan
No textbook information available

15.372 Experimental Innovation Lab
(New)
______

Graduate (Fall)
Prereq: None
Units: 3-3-3
Lecture: T2.30-5.30 (E51-361)
______
Develops the skills needed to run randomized experiments (from design through analysis) in business settings in order to help firms innovate and shape their strategy. Provides foundational knowledge related to the basic structure of a good experiment, analysis methods, randomization, and reasons why even well-planned experiments may fail. Working in small teams, students design, run, and present the results of randomized trials with partner companies. Application required.
D. Sull, N. Thompson
No required or recommended textbooks

15.373[J] Venture Engineering
______

Undergrad (Spring)
(Same subject as2.912[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Develops the capability to move from testing ideas to assembling a venture as a system comprised of technological, human, social, regulatory, managerial, and financial processes and flows that affect costs, revenues, and value. Begins with a focus on leadership, addressing key issues involved in recruiting and building a founder team and its early employees. Fosters understanding of financial resource needs for the new enterprise and methods for raising funds. Students engage in a venture planning activity in which they must demonstrate their understanding of the concepts covered in class.
F. Murray

15.375[J] Development Ventures
______

Graduate (Fall)
(Same subject asEC.731[J],MAS.665[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: R10-12 (E14-633)
______
Seminar on founding, financing, and building entrepreneurial ventures in developing nations. Challenges students to craft enduring and economically viable solutions to the problems faced by these countries. Cases illustrate examples of both successful and failed businesses, and the difficulties in deploying and diffusing products and services through entrepreneurial action. Explores a range of established and emerging business models, as well as new business opportunities enabled by innovations emerging from MIT labs and beyond. Students develop a business plan executive summary suitable for submission in the MIT $100K Entrepreneurship Competition's Accelerate Contest or MIT IDEAS.
J. Bonsen, A. Pentland, C. Breazeal
No textbook information available

15.376[J] Media Ventures
______

Graduate (Spring) Can be repeated for credit
(Same subject asMAS.664[J])
Prereq: None
Units: 3-0-6
______
Seminar surveys internal and external entrepreneurship, based on Media Lab technologies, to increase understanding of how digital innovations grow into societal change. Cases illustrate examples of both successful and failed businesses, as well as difficulties in deploying and diffusing products. Explores a range of business models and opportunities enabled by emerging Media Lab innovations. Students craft a business analysis for one of the featured technology innovations. Past analyses have become the basis for research publications, and new ventures. Particular focus on big data, mobile, and the use of personal data.
A. Pentland, J. Bonsen

15.377[J] Linked Data Ventures
______

Graduate (Spring)
(Same subject as6.932[J])
Prereq: 6.005, 6.033, or permission of instructor
Units: 3-0-9
______
Provides practical experience in the use and development of semantic web technologies. Focuses on gaining practical insight from executives and practitioners who use these technologies in their companies. Working in multidisciplinary teams, students complete a term project to develop a sustainable prototype. Concludes with a professional presentation, judged by a panel of experts, and a technical presentation to faculty.
T. Berners-Lee, L. Kagal, K. Rae, R. Sturdevant

15.378 Building an Entrepreneurial Venture: Advanced Tools and Techniques
______

Graduate (Fall, Spring)
(Subject meets with15.3781)
Prereq: Permission of instructor
Units: 3-1-8
Lecture: M EVE (6-9 PM) (E40-160)
______
Intensive, project-based subject intended for startup teams already working on building a new, high-impact venture. Applies advanced entrepreneurial techniques to build and iterate a venture in a time-compressed manner. Includes weekly coaching sessions with instructors and peers, as well as highly interactive and customized sessions that provide practical, in-depth coverage on key topics in entrepreneurship. Topics include venture creation, primary market research, product development, market adoption, team and culture, and scaling processes with constrained resources. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details. Application required; consult instructor. No listeners.
B. Aulet, J. Baum, E. Chen
No textbook information available

15.3781 Building an Entrepreneurial Venture: Advanced Tools and Techniques
______

Undergrad (Fall, Spring)
(Subject meets with15.378)
Prereq: 15.3901 or permission of instructor
Units: 3-1-8
Lecture: M EVE (6-9 PM) (E40-160)
______
Intensive, project-based subject intended for startup teams already working on building a new, high-impact venture. Applies advanced entrepreneurial techniques to build and iterate a venture in a time-compressed manner. Includes weekly coaching sessions with instructors and peers, as well as highly interactive and customized sessions that provide practical, in-depth coverage on key topics in entrepreneurship. Topics include venture creation, primary market research, product development, market adoption, team and culture, and scaling processes with constrained resources. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details. Application required; consult instructor. No listeners.
B. Aulet, J. Baum, E. Chen
No textbook information available

15.385 Social Innovation and Entrepreneurship
______

Graduate (Spring)
Prereq: 15.911
Units: 3-0-6
______
Students work individually or in teams to develop a business plan for an enterprise (for- or nonprofit) to solve a social problem. They also have the opportunity to develop their skills by working on an existing social venture. Examines the theory and practice of social entrepreneurship and innovation within various social issues and topics, including social impact markets, performance measurement, and theory of change. Students gain practical knowledge on how to identify potential social venture opportunities; develop skills and competencies for creating, developing and implementing ideas; and measure the success and value of a young enterprise.
Staff

15.386 Managing in Adversity
______

Graduate (Fall, Spring); second half of term
Prereq: None
Units: 3-0-3
Begins Oct 31. Lecture: TR10-11.30 (E51-345)
______
Develops the skills required for a CEO to deal with complex problems under highly adverse conditions. Cases and guest CEO speakers present real-life, high-adversity situations that students then deal with through role play. Focuses on how to quickly define issues, determine and evaluate options, and take critical and precipitous actions to address the situation. No listeners.
P. Kurzina
No textbook information available

15.387 Entrepreneurial Sales
______

Not offered academic year 2016-2017Graduate (Fall, Spring)
Prereq: None
Units: 3-0-9
______
Practical and tactical ins and outs of how to sell technical products to a sophisticated marketplace. How to build and manage a sales force; building compensation systems for a sales force, assigning territories, resolving disputes, and dealing with channel conflicts. Focus on selling to customers, whether through a direct salesforce, a channel salesforce, or building an OEM relationship.
L. Shipley

15.389 Global Entrepreneurship Lab
______

Graduate (Fall, IAP)
Prereq: None
Units: 2-0-10
Lecture: TR2.30-4 (E62-276) or TR4-5.30 (E62-276) Recitation: R12 (E62-223)
______
Practical study of the climate for innovation and determinants of entrepreneurial success. Teams of students work with top management in one company to gain experience in running and building a new enterprise. Focuses primarily on start-ups operating in emerging markets. Restricted to graduate students.
S. Johnson, M. Jester
No textbook information available

15.390 New Enterprises
______

Graduate (Fall, Spring)
(Subject meets with15.3901)
Prereq: None
Units: 2-1-6
Lecture: MW2.30-4 (E62-262) or MW4-5.30 (32-141)
______
Covers the process of identifying and quantifying market opportunities, then conceptualizing, planning, and starting a new, technology-based enterprise. Topics include opportunity assessment, the value proposition, the entrepreneur, legal issues, entrepreneurial ethics, the business plan, the founding team, seeking customers and raising funds. Students develop detailed business plans for a start-up. Intended for students who want to start their own business, further develop an existing business, be a member of a management team in a new enterprise, or better understand the entrepreneur and the entrepreneurial process. Meets with 15.3901 when offered concurrently.
W. Aulet, C. Catalini
No textbook information available

15.3901 New Enterprises
______

Undergrad (Fall, Spring)
(Subject meets with15.390)
Prereq: None
Units: 2-1-6
Lecture: MW2.30-4 (E62-262) or MW4-5.30 (32-141)
______
Covers the process of identifying and quantifying market opportunities, then conceptualizing, planning, and starting a new, technology-based enterprise. Topics include opportunity assessment, the value proposition, the entrepreneur, legal issues, entrepreneurial ethics, the business plan, the founding team, seeking customers, and raising funds. Students develop detailed business plans for a start-up. Intended for students who want to start their own business, further develop an existing business, be a member of a management team in a new enterprise, or better understand the entrepreneur and the entrepreneurial process. Meets with 15.390 when offered concurrently. Students taking graduate version complete additional assignments.
W. Aulet, C. Catalini
No textbook information available

15.392 Entrepreneurial Product Development and Marketing
______

Graduate (Spring); first half of term
Prereq: 15.371 or 15.390
Units: 3-0-3
______
Students develop and help market an innovation-driven product that may form the basis of an entrepreneurial start-up, but also could be part of a larger entity. Students use tools and techniques to effectively and efficiently drive product development (hardware or software) in a fast-paced environment, including how to iterate their way to product/market fit, how to generate interest in their start-up through the internet, and how to select the right business model for their market. Application required.
B. Halligan, P. English

15.394 Dilemmas in Founding New Ventures
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.3941
______
Explores key organizational decisions that have far-reaching consequences for founders and their ventures. Though a series of cases, readings, and simulations, students examine five founders' dilemmas: whether and when to found, whom to include in the founding team, how to allocate equity among co-founders, whether to involve external investors, and when and how to exit. Aims to equip students with tools and frameworks to help them understand the implications of early decisions, and to build enduring resources that enable the venture to execute even if the original plan changes substantially. Meets with 15.3941 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
M. Marx

15.3941 Dilemmas in Founding New Ventures
(New)
______

Undergrad (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.394
______
Explores key organizational decisions that have far-reaching consequences for founders and their ventures. Through a series of cases, readings, and simulations, students examine five founders' dilemmas: whether and when to found, whom to include in the founding team, how to allocate equity among co-founders, whether to involve external investors and when and how to exit. Aims to equip students with tools and frameworks to help them understand the implications of early decisions, and to build enduring resources that enable the venture to execute even if the original plan changes substantially. Meets with 15.394 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
M. Marx

15.395 Entrepreneurship Without Borders
______

Graduate (Fall); first half of term
Prereq: None
Units: 3-0-3
Ends Oct 21. Lecture: TR10-11.30 (E62-250)
______
Examines opportunities and problems for entrepreneurs globally, including Europe, Latin America, and Asia. Covers linkages between the business environment, the institutional framework, and new venture creation. Special focus on blockchain technology. In addition to discussing a range of global entrepreneurial situations, student groups pick one particular cluster on which to focus and to understand what further development would entail. Classroom interactions based primarily on case studies.
S. Johnson
No textbook information available

15.396 Seminar in Entrepreneurship
______

Graduate (Spring)
Prereq: None
Units arranged
______
Group study of current topics related to entrepreneurship.
W. Aulet

15.397 Seminar in Entrepreneurship
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Group study of current topics related to high-tech entrepreneurship.
Staff
No textbook information available

15.398 Corporations at the Crossroads: The CEO Perspective
______

Graduate (Spring)
Prereq: None
Units: 2-0-4
______
Focuses on the role of the CEO. Provides a unique opportunity for students to interact with some of the world's leading CEOs who are invited to participate in each class. Topics include the job of the CEO, corporate strategy, career learnings and advice. Emphasizes in particular how the CEO is reacting to critical crossroads.
P. Kurzina

15.399 Entrepreneurship Lab
______

Graduate (Fall, Spring)
Prereq: None
Units: 2-9-1
Lecture: T EVE (6-9 PM) (E51-325)
______
Project-based course, in which teams of students from MIT and Harvard work with startups on problems of strategic importance to the venture. Popular sectors include software, hardware, robotics, cleantech, life sciences. In addition to the regular MIT registration process, students should register at the course website one month before class to facilitate formation of student teams and matching of teams with startup companies.
C. Catalini, J. Dougherty
No textbook information available

Finance

15.401 Managerial Finance
______

Graduate (Fall, Spring)
Prereq: None
Units: 4-0-5
Credit cannot also be received for15.417
Lecture: MW10-11.30 (E51-149) or MW1-2.30 (E51-149) or MW10-11.30 (E51-395) or MW1-2.30 (E51-325, E62-223) Recitation: F2 (E51-149) or F1 (E51-149) or T1 (E62-233, E51-085) or T3 (E62-233) +final
______
Covers the fundamentals of modern financial analysis that are essential to any manager, entrepreneur, investor, or other business professional. Topics include valuation, risk analysis, personal and corporate investment decisions, and an introduction to security analysis and asset management. A prerequisite for all other finance electives offered by the Finance Group. Meets with 15.417 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
Consult K. Nixon
Textbooks (Fall 2016)

15.402 Corporate Finance
______

Graduate (Fall, Spring)
Prereq: 15.401
Units: 3-0-6
Credit cannot also be received for15.418
Lecture: MW10-11.30 (E62-276) or MW1-2.30 (E62-276) +final
______
Introduction to corporate financial management. Topics include capital budgeting, investment decisions and valuation; working capital management, security issues; dividend policy; optimal capital structure; and real options analysis. Meets with 15.418 when offered concurrently.
P. Asquith, A. Malenko
Textbooks (Fall 2016)

15.403 Introduction to the Practice of Finance
______

Graduate (Fall)
Prereq: None
Units: 2-0-1
Lecture: M EVE (4-6 PM) (E62-276)
______
Seminar exposes students to some of the basic institutions and practices of the financial industry. Includes panel discussions with representatives from leading financial institutions, MIT alumni currently engaged in the financial services sector, and leading industry vendors. Restricted to first-year Finance track MBA students.
J. Parsons
No required or recommended textbooks

15.414 Financial Management
______

Graduate (Summer)
Prereq: 15.511
Units: 3-0-6
Credit cannot also be received for15.724
______
Provides a rigorous introduction to the fundamentals of modern financial analysis and applications to business challenges in capital budgeting, project evaluation, corporate investment and financing decisions, and basic security analysis and investment management. Focuses on five key sections: an introduction to the financial system, the unifying principles of modern finance, and fundamental present-value relations; valuation models for both stocks and bonds and capital budgeting; methods for incorporating uncertainty into valuation models; valuation of derivative securities; and applications to corporate financial decisions. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
Staff
No textbook information available

15.415 Finance Theory
______

Graduate (Summer)
Prereq: None
Units: 6-0-9
______
Core theory of capital markets and corporate finance. Topics include functions and operations of capital markets, analysis of consumption-investment decisions of investors, valuation theory, financial securities, risk analysis, portfolio theory, pricing models of risky assets, theory of efficient markets, as well as investment, financing and risk management decisions of firms. Provides a theoretical foundation of finance and its applications. Restricted to students in the Master of Finance Program.
L. Kogan, J. Wang
Textbooks (Summer 2016)

15.416[J] Introduction to Financial Economics
______

Graduate (Fall)
(Same subject as14.416[J])
Prereq: 14.121, 14.122
Units: 4-0-8
Lecture: MW2.30-4 (E51-063) Recitation: F11 (E62-221)
______
Foundations of modern financial economics; individuals' consumption and portfolio decisions under uncertainty; valuation of financial securities. Topics include expected utility theory; stochastic dominance; mutual fund separation; portfolio frontiers; capital asset pricing model; arbitrage pricing theory; Arrow-Debreu economies; consumption and portfolio decisions; consumption beta models; spanning; options; market imperfections; no-trade theorems; rational expectations; financial signaling. Primarily for doctoral students in accounting, economics, and finance.
S. Ross
Textbooks (Fall 2016)

15.417 Laboratory in Investments
______

Undergrad (Spring) Institute Lab
Prereq: None
Units: 4-2-9
Credit cannot also be received for15.401
______
Covers fundamentals of modern financial analysis that are essential to any manager, entrepreneur, investor, or other business professional. Topics include valuation, risk analysis, personal and corporate investment decisions, and an introduction to security analysis and asset management. Laboratory introduces students to methods of modern quantitative finance and to practices of the investment management industry. Projects include implementation and testing of investment strategies and asset pricing models using real-world market data. Instruction and practice in oral and written communication provided.
P. Mende, G. Rao

15.418 Laboratory in Corporate Finance
______

Undergrad (Fall, Spring) Institute Lab
Prereq: 15.417
Units: 4-2-9
Credit cannot also be received for15.402
Lecture: MW10-11.30 (E62-276) or MW1-2.30 (E62-276) Lab: F2.30-4 (E52-164) +final
______
Covers capital budgeting, investment decisions and valuation; working capital management, security issues; dividend policy; optimal capital structure; and real options analysis. Laboratory involves projects of an applied nature in which students either conduct an event study and analyze its impact on firm capital market value, or conduct a merger model between two firms of the student's choosing. Emphasizes use of research databases to test hypotheses. Instruction and practice in communication includes report writing, team projects, and oral and visual presentation. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
S. Myers
Textbooks (Fall 2016)

15.426[J] Real Estate Finance and Investment
______

Graduate (Fall)
(Same subject as11.431[J])
Prereq: Permission of instructor
Units: 4-0-8
Lecture: MW4-5.30 (9-354) Recitation: M EVE (5.30-7 PM) (9-354)
______
Concepts and techniques for analyzing financial decisions in commercial property development and investment. Topics include property income streams, urban economics, discounted cash flow, equity valuation, leverage and income tax considerations, development projects, and joint ventures.
D. Geltner
Textbooks (Fall 2016)

15.427[J] Real Estate Capital Markets
______

Graduate (Spring); first half of term
(Same subject as11.432[J])
Prereq: 11.431; 15.402 or 15.414
Units: 2-0-4
______
Introduces real estate capital markets for institutional investors. Topics include real estate investment trusts (REIT), commercial mortgage-backed securities (CMBS), and private equity. Concepts and techniques for investment analysis include portfolio theory and equilibrium asset pricing. Additional topics may include price indexing and derivatives.
D. Geltner

15.428[J] Tools for Analysis: Design for Real Estate and Infrastructure Development
______

Graduate (Spring); second half of term
(Same subject as11.434[J],IDS.671[J])
Prereq: None
Units: 2-0-4
______
Introduction to analytical tools to support design and decision-making in real estate, infrastructure development, and investment. Particular focus on identifying and valuing sources of flexibility using "real options," Monte-Carlo simulation, and other techniques from the field of engineering systems. Integrates economic and engineering perspectives, and is suitable for students with various backgrounds. Provides useful preparation for thesis work in the area.
D. Geltner, R. de Neufville

15.429[J] Securitization of Mortgages and Other Assets
______

Graduate (Spring)
(Same subject as11.353[J])
Prereq: 15.426, 15.401, or permission of instructor
Units: 3-0-6
______
Investigates the economics and finance of securitization, a practice that allows illiquid assets to be transformed into more liquid securities. Considers the basic mechanics of structuring deals for various asset-backed securities. Investigates the pricing of pooled assets, using Monte Carlo and other option pricing techniques, as well as various trading strategies used in these markets.
W. Torous

15.431 Entrepreneurial Finance and Venture Capital
______

Graduate (Fall)
Prereq: 15.402, 15.414, or 15.415
Units: 3-0-6
Credit cannot also be received for15.4311
Lecture: TR1-2.30 (E51-395) or TR2.30-4 (E51-395) +final
______
Examines the elements of entrepreneurial finance, focusing on technology-based start-up ventures, and the early stages of company development. Addresses key questions which challenge all entrepreneurs: how much money can and should be raised; when should it be raised and from whom; what is a reasonable valuation of a company; and how funding, employment contracts and exit decisions should be structured. Aims to prepare students for these decisions, both as entrepreneurs and venture capitalists. In-depth analysis of the structure of the private equity industry. Meets with 15.4311 when offered concurrently. Expectations and evaluation criteria for graduate students will differ from those of undergraduates; consult syllabus or instructor for specific details.
Staff
No required or recommended textbooks

15.4311 Entrepreneurial Finance and Venture Capital
______

Undergrad (Spring)
Prereq: 15.418
Units: 3-0-6
Credit cannot also be received for15.431
______
Examines the elements of entrepreneurial finance, focusing on technology-based start-up ventures, and the early stages of company development. Addresses key questions which challenge all entrepreneurs: how much money can and should be raised; when should it be raised and from whom; what is a reasonable valuation of a company; and how funding, employment contracts and exit decisions should be structured. Aims to prepare students for these decisions, both as entrepreneurs and venture capitalists. In-depth analysis of the structure of the private equity industry. Meets with 15.431 when offered concurrently. Expectations and evaluation criteria for graduate students will differ from those of undergraduates; consult syllabus or instructor for specific details.
A. Schoar

15.433 Financial Markets
______

Graduate (Fall)
(Subject meets with15.4331)
Prereq: 15.401, 15.414, or 15.415
Units: 3-0-6
Lecture: TR8.30-10 (E52-164) or TR10-11.30 (E52-164) +final
______
Financial theory and empirical evidence for making investment decisions. Topics include portfolio theory; equilibrium models of security prices, including the capital asset pricing model and the arbitrage pricing theory; the empirical behavior of security prices; market efficiency; performance evaluation; and behavioral finance. Meets with 15.4331 when offered concurrently. Students taking graduate version complete additional assignments. Preference to Course 15 students.
J. Pan
Textbooks (Fall 2016)

15.4331 Financial Markets
______

Undergrad (Fall)
(Subject meets with15.433)
Prereq: 15.411
Units: 3-0-6
Lecture: TR8.30-10 (E52-164) or TR10-11.30 (E52-164) +final
______
Covers financial theory and empirical evidence for making investment decisions. Topics include portfolio theory; equilibrium models of security prices, including the capital asset pricing model and the arbitrage pricing theory; empirical behavior of security prices; market efficiency; performance evaluation; and behavioral finance. Meets with 15.433 when offered concurrently. Students taking graduate version complete additional assignments. Preference to Course 15 students.
J. Pan
Textbooks (Fall 2016)

15.434 Advanced Corporate Finance
______

Graduate (Fall, Spring)
(Subject meets with15.4341)
Prereq: 15.402, 15.414, or 15.415
Units: 3-0-6
Lecture: MW10-11.30 (E62-233) or MW1-2.30 (E52-164)
______
Covers advanced topics in corporate finance, including complex valuations, static and dynamic capital structure, risk management, and real options. Also considers security design, restructuring, bankruptcy, corporate control and governance, and international finance issues. Students taking the graduate version complete additional assignments.
N. Bergman
Textbooks (Fall 2016)

15.4341 Advanced Corporate Finance
______

Undergrad (Fall, Spring)
(Subject meets with15.434)
Prereq: 15.418
Units: 3-0-6
Lecture: MW10-11.30 (E62-233) or MW1-2.30 (E52-164)
______
Covers advanced topics in corporate finance, including complex valuations, static and dynamic capital structure, risk management, and real options. Also considers security design, restructuring, bankruptcy, corporate control and governance, and international finance issues. Students taking graduate version complete additional assignments.
N. Bergman
Textbooks (Fall 2016)

15.437 Options and Futures Markets
______

Graduate (Fall)
Prereq: 15.401, 15.414, or 15.415
Units: 3-0-6
Credit cannot also be received for15.4371
Lecture: MW1-2.30 (E51-376) or MW2.30-4 (E51-376)
______
Examines the economic role of options and futures markets. Topics include determinants of forward and futures prices, hedging and synthetic asset creation with futures, uses of options in investment strategies, relation between puts and calls, option valuation using binomial trees and Monte Carlo simulation, implied binomial trees, advanced hedging techniques, exotic options, and applications to corporate securities and other financial instruments. Meets with 15.4371 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. C. Cox
Textbooks (Fall 2016)

15.4371 Options and Futures Markets
______

Undergrad (Fall)
Prereq: 15.417
Units: 3-0-6
Credit cannot also be received for15.437
Lecture: MW1-2.30 (E51-376) or MW2.30-4 (E51-376)
______
Examines the economic role of options and futures markets. Topics include determinants of forward and futures prices, hedging and synthetic asset creation with futures, uses of options in investment strategies, relation between puts and calls, option valuation using binomial trees and Monte Carlo simulation, implied binomial trees, advanced hedging techniques, exotic options, and applications to corporate securities and other financial instruments. Meets with 15.437 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. C. Cox
Textbooks (Fall 2016)

15.438 Fixed Income Securities and Derivatives
______

Graduate (Spring)
Prereq: 15.401, 15.414, or 15.415
Units: 3-0-6
______
Designed for students seeking to develop a sophisticated understanding of fixed income valuation and hedging methods, and to gain familiarity with the major markets and instruments. Emphasizes tools for quantifying, hedging, and speculating on risk. Topics include duration; convexity; modern approaches to modeling the yield curve; interest rate forwards, futures, swaps and options; credit risk and credit derivatives; mortgages; and securitization. 15.437 strongly recommended.
D. Lucas

15.439 Investment Management
______

Graduate (Spring)
Prereq: 15.401, 15.414, or 15.415
Units: 3-0-6
______
Studies financial markets, principally equity markets, from an investment decision-making perspective. Develops a set of conceptual frameworks and tools, and applies them to particular investments and investment strategies chosen from a broad array of companies, securities, and institutional contexts. Focuses strongly on case studies; students are expected to prepare each case before class and participate extensively in discussions.
R. Cohen

15.440[J] Advanced Financial Economics I
______

Graduate (Spring)
(Same subject as14.440[J])
Prereq: 15.416
Units: 5-0-7
______
Covers advanced topics in the theory of financial markets with a focus on continuous time models. Topics include multiperiod securities markets and martingales; pricing of contingent securities such as options; optimal consumption and portfolio problems of an individual; dynamic equilibrium theory and the intertemporal capital asset pricing model; term structure of interest rates; and equilibrium with asymmetric information, transaction costs, and borrowing constraints. Primarily for doctoral students in finance, economics, and accounting.
H. Chen, L. Kogan

15.441[J] Advanced Financial Economics II
______

Graduate (Spring)
(Same subject as14.441[J])
Prereq: 14.121, 14.122, or 15.416J
Units: 3-0-9
______
Surveys selected topics in current advanced research in corporate finance. Theoretical and empirical analyses of corporate financing and investment decisions. Some background in information economics and game theory is useful. Primarily for doctoral students in accounting, economics, and finance.
Staff

15.442[J] Advanced Financial Economics III
______

Graduate (Fall)
(Same subject as14.442[J])
Prereq: 14.382, 15.416J, or permission of instructor
Units: 3-0-9
Lecture: TR2.30-4 (E62-687) Recitation: M EVE (6-7.30 PM) (E51-372)
______
Recent empirical methods in finance, including: the estimation and testing of market efficiency; the random walk hypothesis; the CAPM/APT; various term structure models; option pricing theories; and market microstructures; performance evaluation; bond rating and default analysis; event study methodology; continuous-time econometrics; and general time series methods. An empirical term project is required. Some econometric background and rudimentary computer programming skills are assumed. Primarily for doctoral students in finance, accounting, and economics.
Staff
Textbooks (Fall 2016)

15.444 International Corporate Finance
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 15.402, 15.414, or 15.415
Units: 3-0-6
______
Addresses issues relating to valuation, risk management, financing and contractual design for firms operating in international markets, providing exposure to emerging markets. Students analyze how risk and cash flows should be evaluated in environments with varying levels of risk, such as currency fluctuation, sovereign default, weak property rights, etc. Discusses how certain types of risk can be eliminated or managed through the appropriate design of financial contracts, and how institutional differences across countries shape the structure and efficacy of private equity contracts. Other topics include firm policy and international tax regimes, microfinance, and valuing social return. Concludes with a discussion on the impact of global financial crises on firm financial policy.
Staff

15.445 Mergers and Acquisitions: The Market for Corporate Control
______

Graduate (Spring); partial term
Prereq: 15.515 or 15.516; 15.414, 15.415, orCoreq: 15.402
Units: 2-0-4
Credit cannot also be received for15.4451
______
Examines a corporation's decision to acquire another firm or the decision to oppose being acquired. Explores three aspects of the merger and acquisition process: the strategic decision to acquire, the valuation decision of how much to pay, and the financing decision on how to fund the acquisition. Sessions alternate between discussions of academic readings and applied cases.
N. Gregory

15.4451 Mergers, Acquisitions, and Private Equity
(New)
______

Undergrad (Spring)
Prereq: 15.501;Coreq: 15.402, 15.414, or 15.415
Units: 3-0-6
Credit cannot also be received for15.445
______
Discusses a wide range of topics in corporate mergers and buyout transactions. Covers the mergers and acquisitions market, including classic merger agreements, tax inversions, sale auctions, and hostile takeover law and strategy. Also touches on activist investing and shareholder contests for corporate control. Studies how private equity firms operate and how leveraged buyouts are structured, financed, and valued. Provides opportunity for group work, both in and out of class. Meets with 15.445 when offered concurrently. Expectations and evaluation criteria for graduate students will differ from those of undergraduates; consult syllabus or instructor for specific details.
N. Gregory

15.447 International Capital Markets
______

Graduate (Spring)
Prereq: 15.401, 15.414, or 15.415
Units: 3-0-6
______
Covers globalization of capital markets and implications for financial management of domestic businesses, multinationals, and portfolios. Topics include currency markets, measuring and managing exchange rate exposure, exchange rate determination and forecasting, international financial instruments and institutions, international trading strategies and valuation, and global financial crises.
J. Parker

15.448-15.449 Seminar in Finance
______

Graduate (Fall) Can be repeated for credit
Prereq: 15.402 or 15.414
Units arranged
15.448: TBA.
15.449: TBA.
______
Group study of current topics related to finance.
J. C. Cox
15.448: No textbook information available
15.449: No textbook information available

15.450 Analytics of Finance
______

Graduate (Spring)
Prereq: 15.401, 15.414, or 15.415
Units: 5-0-7
______
Provides a rigorous foundation for the main analytical techniques and quantitative methods necessary to succeed in the financial services industry. Topics include discrete and continuous asset pricing models, financial econometrics, machine learning methods, and dynamic optimization. Examples of applications include portfolio management, risk management, derivative pricing, and algorithmic trading.
H. Chen

15.451 Proseminar in Capital Markets/Investment Management
______

Graduate (Fall)
Prereq: 15.401, 15.414, or 15.415
Units: 2-0-4
Lecture: R EVE (4-6 PM) (E52-164)
______
Provides a unique opportunity to tackle original research problems in capital market analysis and investment management that have been posed by leading experts from the financial community. Students are assigned to teams, and each team is assigned one such problem. Teams present their solutions at a seminar which is attended by representatives of the sponsoring organization and open to the entire MIT community. Not open to students from other institutions.
H. Chen, M. Kritzman
No required or recommended textbooks

15.452 Proseminar in Corporate Finance/Investment Banking
______

Graduate (Fall)
Prereq: 15.402, 15.414, or 15.415
Units: 3-0-3
Lecture: T4-5.30 (E62-262) or T EVE (6-7.30 PM) (E62-262)
______
Bridges the gap between finance theory and finance practice, and introduces students to the broader financial community. Students participate in a series of proseminars with industry guest speakers. Each guest, in collaboration with finance faculty, provides a problem and materials to a team of students. Each team then prepares a report and presents their analysis to the guest speaker and other students for evaluation and feedback. Not open to students from other institutions.
J. Parsons
No required or recommended textbooks

15.460 Financial Engineering
______

Graduate (Fall)
Prereq: 15.401, 15.414, or 15.415
Units: 4-0-5
Lecture: MW2.30-4 (E62-223) +final
______
Provides an introduction to financial engineering, covering topics such as asset pricing theory and applications, optimization, market equilibrium, market frictions, risk management, and advanced topics. Assumes solid undergraduate-level background in calculus, probability, statistics, and programming and includes a substantial coding component. Materials and review sessions use R. Students are encouraged but not required to use R for assignments and projects.
L. Kogan, A. Lo, J. Wang
No required or recommended textbooks

15.466 Functional and Strategic Finance
______

Graduate (Spring)
Prereq: 15.433 or 15.437
Units: 3-0-6
______
Organized around applying finance science and financial engineering in the design and management of global financial institutions, markets, and the financial system - the approach used to understand the dynamics of institutional change and the design of financial products and services. Examines the needs of government as user, producer and overseer of the financial system, including the issues surrounding measuring and managing risks in financial crises. Develops the necessary tools of derivative pricing and risk measurement, portfolio analysis and risk accounting, and performance measurement to analyze and implement concepts and new product ideas. Applies these tools to analyze aspects of the financial crisis of 2007-2009. Preference to MBA and MFin students.
R. Merton

15.467 Asset Management, Lifecycle Investing, and Retirement Finance
______

Graduate (Spring)
Prereq: 15.433
Units: 3-0-6
______
Organized around applying finance science and financial engineering in three related financial-service activities: asset management, lifecycle investing, and retirement finance. Develops the necessary tools of derivative pricing and risk measurement, portfolio analysis and risk accounting, and performance measurement to analyze and implement concepts and new product ideas. Students should be familiar with basic portfolio-selection theory, CAPM, options, futures, swaps and other derivative securities. Preference to MBA and MFin students.
R. Merton

15.481[J] Financial Market Dynamics and Human Behavior
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as6.935[J])
Prereq: 15.401, 15.414, or 15.415
Units: 4-0-5
______
Develops a new perspective on the dynamics of financial markets and the roles that human behavior and the business environment play in determining the evolution of behavior and institutions. Draws on a variety of disciplines to develop a more complete understanding of human behavior in the specific context of markets and other economic institutions. Incorporates practical applications from financial markets, the hedge fund industry, private equity, government regulation, and political economy. Students use ideas from this new perspective to formulate several new hypotheses regarding recent challenges to traditional economic thinking.
A. Lo

15.490 Practice of Finance: Private Equity and Hedge Funds
______

Graduate (Spring); second half of term
Prereq: 15.402, 15.414, or 15.415
Units: 2-0-1
______
Introduction to the field of alternative investments - principally private equity and hedge funds - within the context of the larger investment domain. Covers the structure and operation of alternative funds, valuation, and topics such as deal sourcing, exits, value added, and alpha strategies. Discusses the evolution of the field as well as what the future may bring. Summarizes subfields such as venture capital, leveraged buyouts, distressed investing, and the spectrum of hedge funds. Addresses investor perspectives, portfolio construction and risk management with alternatives. Encourages active student participation, and includes a project and reading list.
P. Cooper

15.491 Practice of Finance: Advanced Corporate Risk Management
______

Graduate (Spring); second half of term
Prereq: 15.402, 15.414, or 15.415
Units: 2-0-4
______
Focuses on how corporations make use of the insights and tools of risk management. Taught from the perspective of potential end-users of derivatives (not the dealer), such as manufacturing corporations, utilities, and software firms. Topics include how companies manage risk, instruments for hedging, liability management and organization, and governance and control. 15.437 recommended.
J. Parsons

15.493 Practice of Finance: Perspectives on Investment Management
______

Graduate (Fall, Spring); second half of term
Prereq: 15.402, 15.414, or 15.415
Units: 3-0-3 [P/D/F]
Begins Oct 31. Lecture: W EVE (4-7 PM) (E51-335)
______
Provides an overview of the investment management industry and an introduction to business fundamentals and valuation. Students read company analyst reports, write papers analyzing various companies, and complete an in-depth company analysis as a final paper. Includes presentations by outside speakers in the investment management industry. Class attendance is mandatory.
J. Shames
Textbooks (Fall 2016)

15.496 Practice of Finance: Data Technologies for Quantitative Finance
______

Graduate (Fall)
Prereq: 15.401, 15.414, or 15.415
Units: 4-0-5
Lecture: T EVE (4-6 PM) (E62-250) Recitation: F9-10.30 (E51-057)
______
Introduces financial market data architecture and design, with applications to asset pricing, quantitative investment strategies, portfolio management, risk management, and high-frequency trading. Studies how data relationships are structured and how to use modern tools and technologies to manipulate, manage, and analyze financial data sets. Uses real-world data, applications, and cases to illustrate principles and provide practical experience.
P. Mende
No required or recommended textbooks

Accounting

15.501 Corporate Financial Accounting
______

Undergrad (Fall, Spring)
(Subject meets with15.516)
Prereq: None
Units: 3-0-9
URL: http://mitsloan.mit.edu/students/academiclife/XReg/15.501.pdf
Lecture: TR1-2.30 (4-237) or TR2.30-4 (4-237) +final
______
Preparation and analysis of financial statements. Focuses on why financial statements take the form they do, and how they can be used in evaluating corporate performance and solvency and in valuation of corporate securities. Introduces concepts from finance and economics (e.g., cash flow discounting and valuation) and explains their relation to, and use in, accounting. Students taking the graduate version complete additional assignments. Permission of Sloan Educational Services required for all cross-registrants.
J. Granja
Textbooks (Summer 2016); Textbooks (Fall 2016)

15.511 Financial Accounting
______

Graduate (Summer)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.720
______
Introduces concepts of corporate financial accounting and reporting of information widely used in making investment decisions, corporate and managerial performance assessment, and valuation of firms. Students perform economics-based analysis of accounting information from the viewpoint of the user (especially senior managers) rather than the preparer (the accountant). Restricted to Sloan Fellows in Innovation and Global Leadership.
J. Weber
No textbook information available

15.514 Financial and Managerial Accounting
______

Graduate (Summer)
Prereq: None
Units: 3-0-9
______
Intensive introduction to the preparation and interpretation of financial information for investors (external users) and managers (internal users) and to the use of financial instruments to support system and project creation. Adopts a decision-maker perspective on accounting and finance. Restricted to System Design and Management students.
S. Keating

15.515 Financial Accounting
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 4-0-5
Lecture: TR8.30-10 (E62-276, E51-335, E62-223) or TR10-11.30 (E62-276, E51-335, E62-223) Recitation: R1 (E62-233, E51-085) or R3 (E51-376) or R4 (E51-149, E51-085) or R3 (E51-149) +final
______
An intensive introduction to the preparation and interpretation of financial information. Adopts a decision-maker perspective of accounting by emphasizing the relation between accounting data and the underlying economic events generating them. Class sessions are a mixture of lecture and case discussion. Assignments include textbook problems, analysis of financial statements, and cases. Restricted to first-year Sloan master's students.
J. Core, R. Verdi
Textbooks (Fall 2016)

15.516 Corporate Financial Accounting
______

Graduate (Fall, Spring, Summer)
(Subject meets with15.501)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://mitsloan.mit.edu/students/academiclife/XReg/15.501.pdf
Lecture: TR1-2.30 (4-237) or TR2.30-4 (4-237) +final
______
See description under subject 15.501. If subject is oversubscribed, priority is given to Course 15 students.
N. Shroff
Textbooks (Summer 2016); Textbooks (Fall 2016)

15.518 Taxes and Business Strategy
______

Graduate (Spring)
Prereq: 15.501, 15.511, 15.515, or 15.516
Units: 3-0-6
Credit cannot also be received for15.5181
______
Provides conceptual framework for thinking about taxation. Topics include taxation of various investments and types of compensation; retirement planning; considerations of choosing an organizational form when starting a business; various methods of mergering, acquiring, and divesting business entities; international tax planning rules and strategies; and high wealth planning and estate tax. Applies current debates on various tax policy options to class discussions. Intended for investment bankers and consultants who need to understand how taxes affect the structure of deals, managers and analysts who need to understand how firms strategically respond to taxes, and entrepreneurs who want to structure their businesses and finances in a tax-advantaged manner. Meets with 15.5181 when offered concurrently. Expectations and evaluation criteria for graduate students will differ from those of undergraduates; consult syllabus or instructor for specific details.
M. Hanlon

15.5181 Taxes and Business Strategy
______

Undergrad (Spring)
Prereq: 15.501
Units: 3-0-6
Credit cannot also be received for15.518
______
Provides conceptual framework for thinking about taxation. Topics include taxation of various investments and types of compensation; retirement planning; considerations of choosing an organizational form when starting a business; various methods of mergering, acquiring, and divesting business entities; international tax planning rules and strategies; and high wealth planning and estate tax. Applies current debates on various tax policy options to class discussions. Meets with 15.518 when offered concurrently. Expectations and evaluation criteria for graduate students will differ from those of undergraduates; consult syllabus or instructor for specific details.
M. Hanlon

15.521 Management Accounting and Control
______

Graduate (Spring)
Prereq: 15.501, 15.511, 15.515, or 15.516
Units: 3-0-6
______
Introduces participants to the language and methodologies of internal accounting practices. Topics include cost allocations, absorption costing, standard costing, transfer pricing, and performance measurement and evaluation. Major focus is on identifying which information is useful and which is useless and potentially misleading.
S. Keating

15.522 Security Design and Corporate Financing
______

Graduate (Spring)
Prereq: 15.401; 15.402 or 15.414; 15.433 or 15.434
Units: 3-0-6
______
Examines how corporations choose securities and markets to finance themselves. These are decisions which the firm must make after it has determined its financial policies including capital structure and dividend policy. Subject discusses recent trends in corporate financing including globalization, secularization, and transformation. Explores new securities and institutional factors, particularly tax and accounting factors that affect their design.
P. Asquith

15.535 Business Analysis Using Financial Statements
______

Graduate (Fall, Spring)
Prereq: 15.501, 15.511, 15.515, or 15.516; 15.401, 15.414, or 15.415
Units: 3-0-6
Lecture: MW1-2.30 (E51-335) or MW2.30-4 (E51-335)
______
Primary learning objective is the strategic, financial, and accounting analysis of a company's profitability and riskiness by means of financial statement data. A second, and related, learning objective is the valuation of a company using financial statement data. Concepts are applied to a number of decision making contexts, including securities analysis, credit analysis, merger analysis, and company performance assessment.
C. Noe
Textbooks (Fall 2016)

15.539 Doctoral Seminar in Accounting
______

Graduate (Fall) Can be repeated for credit
Prereq: 15.515
Units arranged
TBA.
______
Designed primarily for doctoral students in accounting and related fields. The reading list consists of accounting research papers. Objective is to introduce research topics, methodologies, and developments in accounting, and train students to do independent research.
J. Weber
No textbook information available

Information Technologies

15.561 Information Technology Essentials
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: None
Units: 3-0-6
URL: http://web.mit.edu/15.561/www/
______
Examines technology concepts and trends underlying current and future uses of information technology (IT) in business. Emphasis on networks and distributed computing, including the web. Other topics include hardware and operating systems, software development tools and processes, relational databases, security and cryptography, enterprise applications, and electronic commerce. Exposure to web, database, and graphical user interface (GUI) tools. Primarily for Sloan master's students with limited IT background.
T. W. Malone

15.564 IT Essentials II: Advanced Technologies for Digital Business in the Knowledge Economy
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
______
Technologies and concepts for next generation knowledge management and web e-business, including semantic web and web services. Business applications for use in the next two to seven years, including: e-commerce, marketing, finance, trust/security, health/biomedical, mobile. Strategic impacts and entrepreneurial opportunities. Core skills for identifying and evaluating technologies and their business potential, and for managing innovative IT-dependent projects. Overall emphasis on business process automation and e-services.
S. Madnick

15.565[J] Digital Evolution: Managing Web 3.0
______

Graduate (Fall)
(Same subject asIDS.345[J])
Prereq: Permission of instructor
Units: 3-0-6
URL: http://mitsloan.mit.edu/course/15565.html
Lecture: TR2.30-4 (E62-250)
______
Examines the evolution from Web 2.0, with its emphasis on interactivity through online collaboration and sharing among users (primarily through social networking sites, wikis and communication tools), to Web 3.0, which focuses on high proactivity, transforming the Web into a database, and the leveraging of artificial intelligence technologies, such as the Semantic Web. Introduces Management 3.0 and the range of new Web technologies, applications, and business opportunities and challenges that it supports. Addresses topics such as big data, cloud computing, and cybersecurity. Includes case studies, industry and academic speakers, discussion of basic principles, and a team project.
S. Madnick
No textbook information available

15.567 The Economics of Information: Strategy, Structure and Pricing
______

Graduate (Fall); first half of term
Prereq: Permission of instructor
Units: 3-0-3
Ends Oct 21. Lecture: TR1-2.30 (E62-262)
______
Analysis of the underlying economics of information with management implications. Studies effects of digitization and technology on business strategy and organizational structure. Examines pricing, bundling, and versioning of digital goods, including music, video, software, and communication services. Considers the managerial implications of data-driven decision-making, search, targeted advertising, personalization, privacy, network externalities, open source, and alliances. Readings on fundamental economic principles inform provide context for industry speakers and case discussions.
E. Brynjolfsson
No textbook information available

15.569 Leadership Lab: Leading Sustainable Systems
______

Graduate (Fall, IAP)
Prereq: Permission of instructor
Units: 6-0-9
Extra classes: 9/21 and 9/22. Lecture: M2.30-5.30 (E62-233) Recitation: M EVE (5.30-8.30 PM) (E62-233)
______
Addresses key sustainability challenges faced by business and society. Explores alternative ways to view organizations that draw attention to cross-boundary interdependencies and help leaders at all levels develop their capacity to collaborate for systemic change. Develops skills to help students surface and reflect on mental models and practices that keep organizations stuck in unproductive system dynamics. Weaves together theory, experiential practices, guest speakers, and action learning projects that enable teams of students to work with organizations on systemic change initiatives.
P. Senge, W. Orlikowski
Textbooks (Fall 2016)

15.570 Digital Marketing and Social Media Analytics
______

Graduate (Fall); second half of term
Prereq: None
Units: 3-0-3
Begins Oct 31. Lecture: TR1-2.30 (E62-262) or TR2.30-4 (E62-262)
______
Provides a detailed, applied perspective on the theory and practice of digital marketing and social media analytics in the age of big data. Covers concepts such as the difference between earned and paid media, predictive modeling for ad targeting and customer relationship management, measuring and managing product virality, viral product design, native advertising, and engaging the multichannel experience. Stresses the theory and practice of randomized experimentation, AB testing and the importance of causal inference for marketing strategy. Combines lectures, case studies, and guest speakers with relevant industry experience that speak directly to the topics at hand.
S. Aral
No textbook information available

15.571 Enterprise Transformations in the Digital Economy
______

Graduate (Spring)
Prereq: None
Units: 3-0-6
______
Designed to help students understand how the digital economy forces companies to rethink their business strategies--and architect their processes, products, and information. Explores how firms use technology to simplify unnecessary complexity while capitalizing on the value-adding complexity inherent to more global, more integrated, more connected enterprises. Includes case studies about large enterprises using IT to transform how they do business, with guest executives from those enterprises responding to student discussions. Student teams work on consulting projects for major corporaitons.
J. W. Ross

15.572 Analytics Lab: Action Learning Seminar on Analytics, Machine Learning, and the Digital Economy
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-0-7
Lecture: R4-5.30 (E62-262)
______
Student teams design and deliver a project based on the use of analytics, machine learning, large data sets, or other digital innovations to create or transform a business or other organization. Teams may be paired up with an organization or propose their own ideas and sites for the project. Culminates with presentation of results to an audience that includes IT experts, entrepreneurs, and executives.
S. Aral, E. Brynjolfsson
No textbook information available

15.575 Economics of Information and Technology in Markets and Organizations
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
______
Builds upon relevant economic theories and methodologies to analyze the changes in organizations and markets enabled by IT, especially the internet. Typical perspectives examined include industrial organization and competitive behavior, price theory, information economics, intangible asset valuation, consumer behavior, search and choice, auctions and mechanism design, transactions cost economics and incomplete contracts theory, and design of empirical studies. Extensive reading and discussion of research literature aimed at exploring the application of these theories to business issues and challenges raised by the internet and related technologies. Primarily for doctoral students.
E. Brynjolfsson

15.576 Research Seminar in Information Technology and Organizations: Social Perspectives
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: R1-4 (E62-587)
______
Examines the assumptions, concepts, theories, and methodologies that inform research into the social aspects of technology. Extensive reading and discussion of research literature aimed at exploring the multiple social phenomena surrounding the development, implementation, use and implications of information technology in organizations. Primarily for doctoral students.
W. J. Orlikowski
No textbook information available

15.579-15.580 Seminar in Information Technology
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
15.579: URL: http://web.mit.edu/15.579/www/15.579.html
15.579: Lecture: W1-4 (E62-221)
15.580: TBA.
______
Group study of current topics related to information technology.
S. E. Madnick, T. W. Malone, W. Orlikowski
15.579: No textbook information available
15.580: No textbook information available

15.599 Workshop in Digitization
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 2-0-4
TBA.
______
Presentations by faculty, doctoral students, and guest speakers of ongoing research relating to current issues in digitization, technology and the changing economics of work, as well as discussions of key research papers in the field. Specific topics determined by the interest of participants and by new and important directions in digitization, information technology and information economics. Background readings, regular assignments and active participation by students expected. Preference to doctoral students.
E. Brynjolfsson
No textbook information available

Law

15.615 Essential Law for Business
______

Graduate (Fall, Spring)
Prereq: None
Units: 3-0-6
Lecture: MW8.30-10 (E51-149)
______
Provides a broad-gauged introduction to business law, including how law shapes business opportunities and risks. Imparts skills necessary for dealing effectively with law-sensitive aspects of company restructurings and mergers and acquisitions; contracts, complex deals, and financial instruments and facilities; innovation in business models, products, and services; and encounters with regulators. Also discusses individual and organizational accountability to private parties and public authorities, and key legal issues in career transitions.
J. Akula
Textbooks (Fall 2016)

15.616 Basic Business Law, Tilted Towards Key Emerging Issues
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: None
Units: 3-0-6
______
Broad-gauged introduction to business law designed to prepare managers to exercise judgment and leadership when confronting key law-sensitive issues of importance to their organizations and their own careers. Topics include contracts, liability, employment, changing jobs, intellectual property, business disputes, bankruptcy and reorganization, acquisitions, regulatory compliance, and corporate crime. The distinctive feature of 15.616 is an additional focus on newly-emerging, law-sensitive issues of key significance to business. Those topics vary from year to year; some recent examples include doing business in the BRIC nations, and the legal framework of social media.
J. Akula

15.617 Deals, Finance, and the Law
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.6171
______
Addresses law-sensitive issues arising in the overlapping contexts of complex deals and financial services and products. Covers financial services regulation, employment and job changes, and civil and criminal accountability. Develops managerial skills for handling law-sensitive situations at individual and organizational levels. Meets with 15.6171 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. Akula

15.6171 Deals, Finance, and the Law
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.617
______
Addresses law-sensitive issues arising in the overlapping contexts of complex deals and financial services and products. Covers financial services regulation, employment and job changes, and civil and criminal accountability. Develops managerial skills for handling law-sensitive situations at individual and organizational levels. Meets with 15.617 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. Akula

15.618 Entrepreneurship and Innovation: Legal Tools and Frameworks
______

Graduate (Fall, Spring)
Prereq: None
Units: 2-0-4 [P/D/F]
Credit cannot also be received for15.6181
Lecture: T EVE (4-6 PM) (E51-149)
______
Focuses on key law-sensitive issues related to launching and growing a startup, including assembling a team; organizing a business entity; ownership and compensation; early financing; managing contracts, employees, and common early business risks; business distress, winding down, and soft landings; and selling a company. Special attention to innovation-driven ventures built around new technologies or business models. Includes in-depth analysis of the legal framework of cutting-edge technologies and rights in intellectual property. Designed to serve both those with a business background and those engaged in research with commercial potential.
J. Akula
Textbooks (Fall 2016)

15.6181 Entrepreneurship and Innovation: Legal Tools and Frameworks
(New)
______

Undergrad (Spring)
Prereq: None
Units: 2-0-4 [P/D/F]
Credit cannot also be received for15.618
______
Focuses on key law-sensitive issues related to launching and growing a startup, including assembling a team; organizing a business entity; ownership and compensation; early financing; managing contracts, employees, and common early business risks; business distress, winding down, and soft landings; and selling a company. Special attention to innovation-driven ventures built around new technologies or business models. Includes in-depth analysis of the legal framework of cutting-edge technologies and rights in intellectual property. Meets with 15.618 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
J. Akula

15.647-15.649 Seminar in Law
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
15.647: TBA.
15.648: TBA.
15.649: TBA.
______
Group study of current topics related to law.
J. L. Akula
15.647: No textbook information available
15.648: No textbook information available
15.649: No textbook information available

15.657[J] Technology, Globalization, and Sustainable Development
______

Graduate (Fall)
(Same subject as1.813[J],11.466[J],IDS.437[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: W EVE (4-6.30 PM) (E51-376)
______
Investigates sustainable development, taking a broad view to include not only a healthy economic base, but also a sound environment, stable employment, adequate purchasing power, distributional equity, national self-reliance, and maintenance of cultural integrity. Explores national, multinational, and international political and legal mechanisms to further sustainable development through transformation of the industrial state. Addresses the importance of technological innovation and the financial crisis of 2008.
N. Ashford
Textbooks (Fall 2016)

Industrial Relations and Human Resource Management

15.660 Strategic Human Resource Management
______

Graduate (Spring)
Prereq: 15.311
Units: 3-0-6
______
Design and execution of human resource management strategies. Two central themes: How to think systematically and strategically about aspects of managing the organization's human assets, and what really needs to be done to implement these policies and to achieve competitive advantage. Adopts the perspective of a general manager and addresses human resource topics (including reward systems, performance management, high-performance human resource systems, training and development, recruitment, retention, equal employment opportunity laws, work-force diversity, and union-management relationships) from a strategic perspective.
E. J. Castilla

15.662[J] Managing Sustainable Businesses for People and Profits
______

Graduate (Spring)
(Same subject as11.383[J])
Prereq: None
Units: 3-6-3
______
Examines opportunities and challenges involved in building and growing businesses that achieve high financial performance and provide good jobs and careers to employees. Students engage participants in the MITx online course title Shaping the Future of Work to learn about the expectations and employment experiences of workers across the world. Through readings, cases, simulations and class visits from industry leaders, explores the underlying principles and business practices that help to secure that alignment between business health and societal well-being.
T. Kochan

15.663 Environmental Law, Policy, and Economics
(New)
______

Graduate (Fall)
Prereq: None
Units: 3-0-9
Credit cannot also be received for1.801,1.811,11.021,11.630,17.393,IDS.430
Lecture: TR3.30-5 (E51-057)
______
Discusses the roles and interactions of Congress, federal agencies, state governments, and the courts in dealing with environmental problems. Topics include common law, administrative law, environmental impact assessments required by the National Environmental Policy Act. Also covers legislation and court decisions dealing with green-house gas emissions, air pollution, water pollution, the control of toxic chemicals and hazardous waste, pollution and accident prevention, community right-to-know, and environmental justice. Explores the role of science and economics in legal decisions, and economic incentives as an alternative or supplement to regulation. Analyzes pollution as an economic problem and a failure of markets. Provides an introduction to basic legal skills, including how to read and understand cases, regulation, and statutes; how to discover the current state of the law in a specific area; and how to take action toward the resolution of environmental problems.
N. Ashford, C. Caldart
No textbook information available

15.665 Power and Negotiation
______

Graduate (Fall, Spring)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.672,15.6721,15.673,15.6731,15.712
Lecture: R2.30-5.30 (E51-345) or R EVE (6-9 PM) (E51-315)
______
Provides understanding of the theory and processes of negotiation as practiced in a variety of settings. Designed for relevance to the broad spectrum of bargaining problems faced by the manager and professional. Allows students an opportunity to develop negotiation skills experientially and to understand negotiation in useful analytical frameworks. Emphasizes simulations, exercises, role playing, and cases.
J. Curhan
Textbooks (Fall 2016)

15.667 Negotiation and Conflict Management
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
______
Applies negotiation theory strategies and styles to problems managers and professionals commonly encounter in the workplace. Emphasizes sources of power in negotiation, self-assessment of personal negotiating strengths/weaknesses, and practice in negotiations via role-plays and simulations of common workplace conflicts. Covers conflict management as a direct party and as a manager helping others resolve their conflicts through mediation, investigation, arbitration, and helping the system itself to change as a result of a dispute. Special cases include bullying, harassment, dealing with difficult people, cross-cultural negotiations, and collective actions.
T. Kochan

15.668 People and Organizations
______

Undergrad (Spring)
Prereq: None
Units: 3-0-6
______
Examines the historical evolution and current human and organizational contexts in which scientists, engineers and other professionals work. Outlines major challenges facing the management profession. Uses interactive exercises, simulations and problems to develop critical skills in negotiations, teamwork, and leadership. Focuses on practical application of these skills in a professional context. Introduces concepts and tools to analyze work and leadership experiences in internships, school activities, and fieldwork. Preference to Management minors and other undergraduates not majoring in Management Science.
T. Kochan, P. Osterman

15.671 U-Lab: Transforming Self, Business and Society
______

Graduate (Fall); first half of term
Prereq: None
Units: 3-0-3 [P/D/F]
Ends Oct 21. Lecture: R EVE (5.30-9 PM) (E62-233)
______
Experiential opportunity to practice new leadership skills, such as deep listening, being present (mindfulness), and generative dialogue. In weekly coaching circles, each student has one full session to present their current leadership edge and receive feedback from peer coaches. Includes an additional action learning project.
O. Scharmer
Textbooks (Fall 2016)

15.672 Negotiation Analysis
______

Graduate (IAP)
(Subject meets with15.6721,15.673,15.6731)
Prereq: Permission of instructor
Units: 1-0-2 [P/D/F]
Credit cannot also be received for15.665,15.712
URL: http://negotiation.mit.edu/
______
Presents analytical frameworks and strategies to handle a variety of negotiation situations. Includes simulations, games, videos, lectures, discussion, and multiple opportunities to practice and hone negotiation, communication, and influence skills with extensive personalized feedback. Intended for students with a broad spectrum of backgrounds and experience levels. Six-unit version includes additional class time and outside work. Expectations and evaluation criteria differ for students taking graduate version. Limited to 80 via lottery; consult class website for information and deadlines.
J. Curhan

15.6721 Negotiation Analysis
______

Undergrad (IAP)
(Subject meets with15.672,15.673,15.6731)
Prereq: Permission of instructor
Units: 1-0-2 [P/D/F]
Credit cannot also be received for15.665,15.712
URL: http://negotiation.mit.edu/
______
Presents analytical frameworks and strategies to handle a variety of negotiation situations. Includes simulations, games, videos, lectures, discussion, and multiple opportunities to practice and hone negotiation, communication, and influence skills with extensive personalized feedback. Intended for students with a broad spectrum of backgrounds and experience levels. Six-unit version includes additional class time and outside work. Expectations and evaluation criteria differ for students taking graduate version. Limited to 80 via lottery; consult class website for information and deadlines.
J. Curhan

15.673 Negotiation Analysis
______

Graduate (IAP)
(Subject meets with15.672,15.6721,15.6731)
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Credit cannot also be received for15.665,15.712
URL: http://negotiation.mit.edu/
______
Presents analytical frameworks and strategies to handle a variety of negotiation situations. Includes simulations, games, videos, lectures, discussion, and multiple opportunities to practice and hone negotiation, communication, and influence skills with extensive personalized feedback. Intended for students with a broad spectrum of backgrounds and experience levels. Six-unit version includes additional class time and outside work. Expectations and evaluation criteria differ for students taking graduate version. Limited to 80 via lottery; consult class website for information and deadlines.
J. Curhan

15.6731 Negotiation Analysis
______

Undergrad (IAP)
(Subject meets with15.672,15.6721,15.673)
Prereq: Permission of instructor
Units: 2-0-4 [P/D/F]
Credit cannot also be received for15.665,15.712
URL: http://negotiation.mit.edu/
______
Presents analytical frameworks and strategies to handle a variety of negotiation situations. Includes simulations, games, videos, lectures, discussion, and multiple opportunities to practice and hone negotiation, communication, and influence skills with extensive personalized feedback. Intended for students with a broad spectrum of backgrounds and experience levels. Six-unit version includes additional class time and outside work. Expectations and evaluation criteria differ for students taking graduate version. Limited to 80 via lottery; consult class website for information and deadlines.
J. Curhan

15.676 Work, Employment, and Industrial Relations Theory
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 2-0-7
______
Historical evolution and assessment of different theories and disciplinary perspectives used in research on work, employment, and industrial relations. Introduces doctoral students to the field and explores where their research interests fit within the broader field. First part compares the normative assumptions, theories, and methodologies used by economists, historians, sociologists, psychologists, political scientists, and legal scholars from the latter nineteenth century to the present. Final portion explores strategies for advancing research on topics of current interest to participants.
T. Kochan, P. Osterman, E. Castilla, O. Sharone, M. Amengual

15.677[J] Urban Labor Markets and Employment Policy
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as11.427[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Discusses the broader trends in the labor market, how urban labor markets function, public and private training policy, other labor market programs, the link between labor market policy and economic development, and the organization of work within firms.
P. Osterman

15.678[J] Political Economy I: Theories of the State and the Economy
______

Graduate (Spring)
(Same subject as14.781[J],17.100[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Critical analysis of liberal, neoclassical, and Marxist perspectives on modern society. Alternative theories of economic growth, historical change, the state, classes, and ideology.
M. Piore, S. Berger

15.691 Research Seminar in Work, Employment and Industrial Relations
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Discusses important areas for research in work, employment and industrial relations; frameworks for research, research techniques, and methodological problems. Centered mainly on staff research and the thesis research of advanced graduate students and invited guests.
Consult T. A. Kochan
No textbook information available

15.698 Seminar in Industrial Relations and Human Resource Management
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Group study of current topics related to industrial relations and human resource management.
Consult P. Osterman
No textbook information available


left arrow|15.00-15.299|15.30-15.699|15.70-15.999 plus UROP and Thesis|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 15: Management
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Course 15: Management
Fall 2016


Executive MBA Subjects

15.700 Leadership and Integrative Management
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6 [P/D/F]
Lecture: TBA
______
Investigates the different perspectives a general manager must take, how to integrate those perspectives, and the role of leadership in setting and realizing goals. Students work intensively in teams and with multiple faculty, using a deep dive into the challenges faced by a major global firm operating in complex global markets. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.701 Innovation-Driven Entrepreneurial Advantage
______

Graduate (Spring, Summer)
Prereq: 15.714 or permission of instructor
Units: 6-0-6
______
Exposes students to the content, context, and contacts that enable entrepreneurs to design and launch successful stand-alone ventures, ventures inside established corporations, and ventures in partnership with established corporations based on new innovations. Students examine the critical entrepreneurial and innovation challenges facing entrepreneurs inside new and established firms, and develop frameworks that allow them to identify, evaluate, iterate, and integrate their ideas effectively. Case-based discussions complemented by visits to key actors in MIT labs, as well as live case studies with successful entrepreneurs. Specially designed team projects provide practical experience in entrepreneurial strategy, innovation management, and the workings of the MIT entrepreneurial ecosystem. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.702 Leading in a Global Context: Macroeconomics and Global Markets
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 6-0-6
Lecture: TBA
______
Intensive module on the global economy, combining the key perspectives of macroeconomics and global economic strategy. Focuses on the policy and economic environment of firms, as well as on the development of a more international market in products, services, and capital, and how this affects trade and industries. Presents insights into national economic strategies for development, and into the evolving rules and institutions governing the international economic order. Develops an actionable appreciation for managers of the international dimensions of economic policy and strategy in an increasingly complex world economy. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.703 Leading with Impact
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
______
Strengthens students' skills in recognizing, developing, and taking advantage of opportunities created by organizational complexity. Focuses on key topics in corporate strategy, organizational design, organizational economics, and strategic human resource management, as well as themes such as integrative management, global leadership, and innovation and entrepreneurship strategy. Emphasizes teaching through integrative, multi-perspective cases, and reflection to prepare students for the next steps in their careers as general managers. Includes two projects where students create a plan for implementing a change initiative within their organization, and develop a career plan. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.705 Organizations Lab
______

Graduate (Fall, Summer)
Prereq: Permission of instructor orCoreq: 15.716
Units: 3-0-9
Lecture: TBA
______
Preparation for an organizational change project. Emphasis on applying tools of organizational, operational, and systems analysis in order to effect change. Includes a focus on the challenges and opportunities presented by issues of leadership and organizational behavior. Each student leads a change project in his or her own organization, focusing on fixing a broken or ineffective process. Examples of possible initiatives include a strategic reorientation, organizational restructuring, introduction of a new technology, a worker participation program, etc. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.707 Global Strategy
______

Graduate (Fall, Spring)
Prereq: Permission of instructor;Coreq: 15.708
Units: 3-0-3
TBA.
______
Provides students with the evidence, concepts and models for understanding company performance in a global world and the issues facing executives in the early 21st century. Prepares students to manage effectively in todays interconnected world by understanding this changing environment, principles of global strategy, and the relation between global strategy and organization. Focuses on the specificities of strategy and organization of the multinational company. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.708 Global Organizations Lab
______

Graduate (Fall, Spring)
Prereq: Permission of instructor;Coreq: 15.707
Units: 6-0-9
Lecture: TBA
______
Helps students discover and develop new and effective ways of managing and working together across national borders; also helps accelerate development of the context awareness and integrative management skills needed to lead in a globalized world. Involves intensive team engagement with a firm where students integrate their understanding of the relevant global and national economic and institutional contexts, industry dynamics, the firm's strategic position and capabilities, and its management organization and processes to provide the management sponsor with insight and effective recommendations. Includes a week-long site visit for research. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.712 Power and Negotiation
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-3
Credit cannot also be received for15.665,15.672,15.6721,15.673,15.6731
______
Provides understanding of the theory and processes of negotiation as practiced in a variety of settings. Designed for relevance to the broad spectrum of bargaining problems faced by the manager and professional. Allows students an opportunity to develop negotiation skills experientially and to understand negotiation in useful analytical frameworks. Emphasizes simulations, exercises, role playing, and cases. Restricted to Executive MBA students.
Consult J. Lehrich

15.714 Competitive Strategy
______

Graduate (IAP, Spring, Summer)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.902
______
Introduces a variety of modern strategy frameworks and methodologies to develop the skills needed to be a successful manager. Cases and readings explore a range of strategic problems, focusing particularly on the sources of competitive advantage and the interaction between industry structure and organizational capabilities. Emphasizes the perspective of the general manager in ensuring the firm's success. Encourages awareness of both the external (market) and internal (organizational) forces that shape firm performance. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.716 Leading Organizations
______

Graduate (Summer)
Prereq: None
Units: 3-0-6 [P/D/F]
Credit cannot also be received for15.322
______
Promotes awareness of and strategies to meet the key challenges leaders face today (and tomorrow). Acquaints students with some of the psychological and sociological dynamics that regularly operate in organizational settings - the less visible but quite powerful "forces" that shape the way employees and managers respond (or don't respond) to a changing world. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.717 Organizational Processes
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Lecture: TBA
______
Designed to enhance students' ability to take effective action in complex organizational settings by providing the analytic tools needed to analyze, manage, and lead the organizations of the future. Emphasizes the importance of the organizational context in influencing which individual styles and skills are effective. Employs a wide variety of learning tools, from experiential learning to the more conventional discussion of written cases. Centers on three complementary perspectives on organizations: the strategic design, political, and cultural "lenses" on organizations. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.720 Financial Accounting
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.511
______
Examines the basic concepts of corporate financial accounting and reporting, and the role of accounting information in investment decisions, corporate and managerial performance assessment, and the valuation of firms. Develops skills for performing an economics-based analysis of accounting information from the viewpoint of the users of accounting information (especially senior managers), rather than the preparer (the accountant). Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.722 Applied Economics for Managers
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.024
Lecture: TBA
______
Develops facility with concepts, language, and analytical tools of economics. Primary focus is on microeconomics. Emphasizes integration of theory, data, and judgment in the analysis of corporate decisions and public policy, and in the assessment of changing US and international business environments. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.723 Advanced Applied Macroeconomics and International Institutions
______

Graduate (IAP, Spring)
Prereq: 15.702 or permission of instructor
Units: 3-0-3
______
Topics draw on current macroeconomic issues and events, such as modern monetary and fiscal policy; financial crisis, contagion, and currency crisis; real exchange rates, purchasing power parity, and long run sustainability; sustainable development; targeting and the new monetary policy regime; and Europe and the Euro: optimal currency areas. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.724 Financial Management
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.414
Lecture: TBA
______
Introduction to corporate finance and capital markets. Topics include project and company valuation, real options, measuring risk and return, stock pricing and the performance of trading strategies, corporate financing policy, the cost of capital, and risk management. Subject provides a broad overview of both theory and practice. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.725 Advanced Marketing Strategy
______

Graduate (IAP)
Prereq: None
Units: 1-0-2
______
Helps students consider the entire marketing mix in light of the strategy of the firm. Reviews customer-based sources of competitive advantage and discusses how to identify, measure, and leverage them. Introduces a method for comparing alternative selling formats (e.g., brick and mortar vs. electronic), aiming to find the most efficient ways to sell different products to different customers. Discusses the myriad ways in which the firm can grow its sources of competitive advantage. Provides practical experience in using tools to identify, evaluate, and develop marketing strategies; design efficient products and selling formats; and plan the use and development of the firm's portfolio of resources. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.726 Pricing
______

Graduate (IAP)
Prereq: None
Units: 1-0-2
Credit cannot also be received for15.818
______
Focuses on practical pricing tactics. Presents a framework for the steps firms should take when thinking about pricing a new product or improving the pricing performance of an old product. Tools covered include monadic pricing surveys, empirical price elasticity calculations, and conjoint. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.727 The Analytics Edge
______

Graduate (Spring)
Prereq: 15.730 or permission of instructor
Units: 3-0-3
______
Introduces modern analytics methods (data mining and optimization), starting with real-world problems where analytics have made a material difference. Modern data mining methods include clustering, classification, logistic regression, CART, random forest methods, and association rules. Modern optimization methods include robust, adaptive and dynamic optimization. Applications include health care, hospital operations, finance, energy, security, internet, and demand modeling. Uses R programming language for data mining and ROME for robust optimization. Restricted to Exeuctive MBA students.
Consult J. Hising DiFabio

15.728 Law and Strategy for the Senior Executive
______

Graduate (IAP)
Prereq: None
Units: 1-0-2
______
Designed to provide the judgment skills needed to plan, manage, and lead when confronting key law-sensitive issues in one's organization and career. Reviews how the law structures both the risks and opportunities relating to issues such as regulatory compliance, major liability exposure, and intellectual property rights. Special attention to how these play out in the context of new technologies. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.730 Data, Models, and Decisions
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.060
______
Introduces students to fundamental tools in using data to make informed management decisions. Emphasizes the executive perspective: how to leverage best-practice quantitative methods to manage and drive the business. Exercises and cases complemented by perspectives and applications in finance, operations management, healthcare, the Internet, and other functions and industries. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.732 Marketing Management
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.809,15.812
Lecture: TBA
______
Studies the application of a reasoned framework to the selection of target markets and the optimization of marketing decisions. Subject is divided into two parts: a tactical portion that reviews how firms optimize profits in their chosen markets, and a strategic portion that focuses on identifying target markets. Tactical topics include pricing, promotion, channel and product issues. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.734 Introduction to Operations Management
______

Graduate (Summer)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.761,15.7611
______
Provides concepts, techniques and tools to design, analyze and improve core strategic operational capabilities. Covers a broad range of application domains and industries, such as high-tech, financial services, insurance, automotive, health care, retail, fashion, and manufacturing. Emphasizes the effects of uncertainty in business decision making and the interplay between strategic and financial objectives and operational capabilities. Students play simulation games that demonstrate some of the central concepts. Restricted to Executive MBA students.
Consult J. Hising DiFabio
No textbook information available

15.736 Introduction to System Dynamics
______

Graduate (Summer)
Prereq: Permission of instructor
Units: 3-0-6
Credit cannot also be received for15.871
______
Introduces system dynamics modeling for the analysis of business policy and strategy. Provides the skills to visualize an organization in terms of the structures and policies that create dynamics and regulate performance. Uses causal mapping, simulation models, case studies, and management flight simulators to help develop principles of policy design for successful management of complex strategies. Considers the use of systems thinking to promote effective organizational learning. Restricted to Executive MBA students.
Consult J. Lehrich
No textbook information available

15.737 Advanced System Dynamics
______

Graduate (IAP)
Prereq: 15.736 or permission of instructor
Units: 3-0-0 [P/D/F]
Credit cannot also be received for15.872
______
Workshops focus on two models: the dynamics of service quality within a firm; and industry dynamics (particularly investment cycles and bubbles), including the energy and housing markets. Emphasis on formulation, analysis, use, and decision-making. Develops modeling skills. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.738 Topics in Corporate Finance
______

Graduate (IAP)
Prereq: 15.724
Units: 1-0-2
______
Case studies and lectures introduce financial tools needed to make value-enhancing business decisions. Topics drawn from issues such as advanced valuation analysis, capital structure decisions, debt restructuring, bankruptcy, incentive problems, real options, and valuation of international projects. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.739 Discovering Your Leadership Signature
______

Graduate (IAP)
Prereq: None
Units: 1-0-2
Credit cannot also be received for15.318
______
Helps students understand their unique way of leading, i.e., leadership signature. Provides tools for students to determine what kind of leader they are and how to tell their leadership story. Examines leadership identity, drawing on theory from leadership literature, family systems, developmental psychology, personality psychology, and organizational change. Also builds on the four capabilities (4-CAP) model. Includes case studies, reflection, video analysis, and storytelling. Restricted to Executive MBA students.
Consult J. Hising DiFabio

15.740 Strategic Communication for Executives
______

Graduate (IAP)
Prereq: None
Units: 1-0-2
______
Develops communication skills crucial to successful management. Focuses on identifying a range of communication styles, and recognizing how to use them; dealing successfully with challenging or hostile audiences; understanding cross-cultural and global communication issues and differences; and leading and communicating in a crisis situation. Restricted to Executive MBA students.
Consult J. Hising DiFabio

Operations Management

15.761 Introduction to Operations Management
______

Graduate (Fall, Spring, Summer)
Prereq: 15.060, 6.041B, or permission of instructor
Units: 4-0-5
Credit cannot also be received for15.734,15.7611
Lecture: MW1-2.30 (E51-315) Recitation: F2 (E51-345)
______
Imparts concepts, techniques, and tools to design, analyze, and improve core operational capabilities and apply them to a broad range of application domains and industries. Emphasizes the effect of uncertainty in decision-making, as well as the interplay among high-level financial objectives, operational capabilities, and people and organizational issues. Covers topics in capacity analysis, process design, process and business innovation, inventory management, risk pooling, supply chain coordination, sustainable operations, quality management, operational risk management, pricing and revenue management. Underscores how these topics are integrated with the different functions of the firm. Case studies and simulation games provide experience in applying central concepts and techniques to solve real-world business challenges. Meets with 15.7611 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details. Summer section is primarily for Leaders for Global Operations students.
R. Levi, T. Zaman, K. Zheng
No textbook information available (Summer 2016); Textbooks (Fall 2016)

15.7611 Introduction to Operations Management
______

Undergrad (Spring)
Prereq: 6.041B or permission of instructor
Units: 4-0-5
Credit cannot also be received for15.734,15.761
______
Imparts concepts, techniques, and tools to design, analyze, and improve core operational capabilities and apply them to a broad range of application domains and industries. Emphasizes the effect of uncertainty in decision-making, as well as the interplay among high-level financial objectives, operational capabilities, and people and organizational issues. Covers topics in capacity analysis, process design, process and business innovation, inventory management, risk pooling, supply chain coordination, sustainable operations, quality management, operational risk management, pricing and revenue management. Underscores how these topics are integrated with the different functions of the firm. Case studies and simulation games provide experience in applying central concepts and techniques to solve real-world business challenges. Meets with 15.761 when offered concurrently. Expectations and evaluation criteria differ for students taking graduate version; consult syllabus or instructor for specific details.
T. Zaman, K. Zheng
No textbook information available

15.762[J] Supply Chain Planning
______

Graduate (Spring)
(Same subject as1.273[J],IDS.150[J])
Prereq: 1.260 or 15.761
Units: 2-0-4
______
Focuses on effective supply chain strategies for companies that operate globally, with emphasis on how to plan and integrate supply chain components into a coordinated system. Students are exposed to concepts and models important in supply chain planning with emphasis on key tradeoffs and phenomena. Introduces and utilizes key tactics such as risk pooling and inventory placement, integrated planning and collaboration, and information sharing. Lectures, computer exercises, and case discussions introduce various models and methods for supply chain analysis and optimization. Recommended for Operations Management concentrators. First half-term subject.
Staff

15.763[J] Manufacturing System and Supply Chain Design
______

Graduate (Spring)
(Same subject as1.274[J],IDS.151[J])
Prereq: 1.260, 15.761, or 15.778
Units: 2-0-4
______
Focuses on decision making for system design, as it arises in manufacturing systems and supply chains. Students exposed to frameworks and models for structuring the key issues and trade-offs. Presents and discusses new opportunities, issues and concepts introduced by the internet and e-commerce. Introduces various models, methods and software tools for logistics network design, capacity planning and flexibility, make-buy, and integration with product development. Industry applications and cases illustrate concepts and challenges. Recommended for Operations Management concentrators. Second half-term subject.
S. C. Graves, D. Simchi-Levi

15.764[J] The Theory of Operations Management
______

Graduate (Spring) Can be repeated for credit
(Same subject as1.271[J],IDS.155[J])
Prereq: 15.081J or 6.251J, 6.436J; or permission of instructor
Units: 3-0-9
______
Provides mathematical foundations underlying the theory of operations management. Covers application domains, including inventory management, supply chain management and logistics, behavioral operations, healthcare management, service industries, pricing and revenue management, and auctions. Studies a wide range of mathematical and analytical techniques, such as dynamic programming, stochastic orders, behavioral and experimental economics, algorithms and approximations, data-driven and learning models, and mechanism design. Also provides hands-on experience in how to apply the theoretical models to solve OM problems in concrete business settings. Specific topics vary from year to year.
I. Ashlagi, D. Simchi-Levi, K. Zheng

15.765[J] Global Supply Chain Management
______

Graduate (Spring)
(Same subject as1.265[J],2.965[J],SCM.265[J])
Prereq: 1.260, 1.261, 15.761, 15.778, or permission of instructor
Units: 2-0-4
______
Focuses on the planning, processes, and activities of supply chain management for companies involved in international commerce. Students examine the end-to-end processes and operational challenges in managing global supply chains, such as the basics of global trade, international transportation, duty, taxes, trade finance and hedging, currency issues, outsourcing, cultural differences, risks and security, and green supply chains issues. Highly interactive format features student-led discussions, staged debates, and a mock trial. Includes assignments on case studies and sourcing analysis, as well as projects and a final exam.
B. Arntzen

15.767 Healthcare Lab: Introduction to Healthcare Delivery in the United States
______

Graduate (Fall)
(Subject meets with15.777)
Prereq: 15.060, 15.761; or permission of instructor
Units: 4-0-5
Lecture: MW10-11.30 (E62-250) Recitation: F1-2.30 (E62-221)
______
Focuses on the current business challenges and opportunities to deliver high quality and reasonably priced health services. Provides students the opportunity to interact with speakers and many senior executives from the health industry. Topics include healthcare reform, systematic scheduling, retail clinics, telehealth, entrepreneurship, community health, etc. Discussions include practical examples from the ongoing healthcare-related work of Sloan faculty and projects with local hospitals. Provides a broad perspective on various career paths, such as consulting, entrepreneurship, hospital management, and IT innovation. Student teams work directly with a health organization on an applied project, which includes onsite work during SIP week. Students who choose our international projects or projects out of the Boston area will do their onsite project (register for 15.777) during IAP with permission of the instructor and organization; consult instructors for information.
R. Levi, J. Wilkinson
No textbook information available

15.768 Management of Services: Concepts, Design, and Delivery
______

Graduate (Spring)
Prereq: 15.761, 15.778, or permission of instructor
Units: 3-0-6
______
Explores the use of operations tools and perspectives in the service sector, including both for-profit and not-for-profit organizations. Builds on conceptual frameworks and cases from a wide range of service operations, selected from health care, hospitality, internet services, supply chain, transportation, retailing, food service, entertainment, financial services, humanitarian services, government services, and others.
C. Fine, Z. Ton

15.769 Operations Strategy
______

Graduate (Fall, Spring)
Prereq: 15.761, 15.778, or permission of instructor
Units: 3-0-6
Lecture: TR8.30-10 (E62-250)
______
Provides unifying framework for analyzing strategic issues in manufacturing and service operations. Covers decisions in technology, facilities, vertical integration, human resources and other strategic areas. Explores means of competition, such as cost, quality, speed, innovativeness, and how operations companies address growth. Presents students with an approach to make operations decisions in the era of outsourcing and globalization.
T. Roemer, D. B. Rosenfield, Z. Ton
Textbooks (Fall 2016)

15.770[J] Logistics Systems
______

Graduate (Fall)
(Same subject as1.260[J],IDS.730[J],SCM.260[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: MW8.30-10 (E51-315)
______
Provides an introduction to supply chain management from both analytical and practical perspectives. Taking a unified approach, students develop a framework for making intelligent decisions within the supply chain. Covers key logistics functions, such as demand planning, procurement, inventory theory and control, transportation planning and execution, reverse logistics, and flexible contracting. Explores concepts such as postponement, portfolio management, and dual sourcing. Emphasizes skills necessary to recognize and manage risk, analyze various tradeoffs, and model logistics systems.
Y. Sheffi, C. Caplice
Textbooks (Fall 2016)

15.771[J] Case Studies in Logistics and Supply Chain Management
______

Graduate (Spring)
(Same subject as1.261[J],SCM.261[J])
Prereq: Permission of instructor
Units: 3-0-6
______
A combination of lectures and cases covering the strategic, management, and operating issues in contemporary logistics and integrated supply chain management. Includes: logistics strategy; supply chain restructuring and change management; and distribution, customer service, and inventory policy.
J. Byrnes

15.772[J] D-Lab: Supply Chains
______

Undergrad (Fall)
(Same subject asEC.733[J])
Prereq: None
Units: 3-3-6
Lecture: MW10-11.30 (1-134)
______
Introduces concepts of supply chain design and planning with a focus on supply chains for products destined to improve quality of life in developing countries. Topics include demand estimation, process analysis and improvement, facility location and capacity planning, inventory management, and supply chain coordination. Also covers issues specific to emerging markets, such as sustainable supply chains, choice of distribution channels, and how to account for the value-adding role of a supply chain. Students conduct D-Lab-based projects on supply chain design or improvement.
S. C. Graves
No textbook information available

15.777 Healthcare Lab: Introduction to Healthcare Delivery in the United States
______

Graduate (Fall, IAP)
(Subject meets with15.767)
Prereq: 15.060, 15.761
Units: 4-0-11
Lecture: MW10-11.30 (E62-250) Recitation: F1-2.30 (E62-221)
______
Focuses on the current business challenges and opportunities to deliver high quality and reasonably priced health services. Provides students the opportunity to interact with speakers and many senior executives from the health industry. Topics include healthcare reform, systematic scheduling, retail clinics, telehealth, entrepreneurship, community health, etc. Discussions include practical examples from the ongoing healthcare-related work of Sloan faculty and projects with local hospitals. Provides a broad perspective on various career paths, such as consulting, entrepreneurship, hospital management, and IT innovation. Student teams work directly with a health organization on an applied project, which includes onsite work during SIP week. Students who choose our international projects or projects out of the Boston area will do their onsite project (register for 15.777) during IAP with permission of the instructor and organization; consult instructors for information.
R. Levi, J. Wilkinson
No textbook information available

15.778 Introduction to Operations Management
______

Graduate (Summer)
Prereq: None
Units: 3-0-6
______
Integrated approach to the analysis, design and management of supply networks for products and services. Provides a framework for analysis, design and operation of supply chains (SCs) that relies on fundamental concepts, such as the management of inventory, and operations and logistics planning. Discusses the value of (timely) information and of the need for collaboration and coordination between SC players. Also presents conceptual frameworks that focus on the emergence of a wide range of enabling services that are critical to the survival and growth of this class of system. Includes study and discussion of concepts, examples, and case studies from a wide range of industries. Guest speakers present personal experiences on various aspects of the service industry and supply chains. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
Consult C. Fine
No textbook information available

15.780 Stochastic Models in Business Analytics
______

Undergrad (Fall)
Prereq: 6.041B, 15.079, or permission of instructor
Units: 3-0-9
Lecture: TR11.30-1 (E62-262) Recitation: F2 (E51-325) +final
______
Introduces core concepts in data-driven stochastic modeling that inform and optimize business decisions under uncertainty. Covers stochastic models and frameworks, such as queuing theory, time series forecasting, network models, dynamic programming, and stochastic optimization. Draws on real-world applications, with several examples from retail, healthcare, logistics, supply chain, social and online networks, and sports analytics.
R. Levi, K. Zheng
No textbook information available

15.783[J] Product Design and Development
______

Graduate (Spring)
(Same subject as2.739[J])
Prereq: 2.009, 15.761, 15.778, 15.810, or permission of instructor
Units: 3-3-6
URL: http://web.mit.edu/15.783j/www/
______
Covers modern tools and methods for product design and development. Includes a cornerstone project in which teams conceive, design and prototype a physical product and/or service. Covers design thinking, product planning, identifying customer needs, concept generation, product architecture, industrial design, concept design, green design methods, and product management. Sloan students register via Sloan course bidding. Engineering students accepted via lottery based on WebSIS pre-registration.
S. Eppinger, M. C. Yang

15.784 Operations Laboratory
______

Graduate (Spring)
Prereq: None.Coreq: 15.761
Units: 2-3-4
______
Provides an interactive learning experience in implementing operations improvement. Teams of 3-5 students act as consultants on operations engagements in small- to medium-sized Boston-area organizations. Class time focuses on project management, implementation issues for and examples from company settings (particularly small ones), and team report-outs and discussions. Organizations include small manufacturing companies as well as service organizations, such as hospitals and non-profits, providing a wide range of real operational problems in various environments.
D. Rosenfield, Z. Ton

15.792[J] Global Operations Leadership Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as2.890[J],10.792[J],16.985[J])
Prereq: None
Units arranged [P/D/F]
Lecture: M EVE (4-6 PM) (E62-262)
______
Integrative forum in which worldwide leaders in business, finance, government, sports, and education share their experiences and insights with students aspiring to run global operations. Students play a large role in managing the seminar. Preference to LGO students.
T. Roemer
No textbook information available

15.794 Research Project in Operations
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Designed for Leaders for Global Operations (LGO) students in conjunction with on-site projects at LGO partner companies. Student teams work on faculty-supervised thesis research projects that deal with a specific aspect of operations. Students required to summarize their work in the context of understanding organization, leadership, teamwork, and task management in conjunction with 15.317.
T. Roemer
No textbook information available

15.795 Behavioral Decision Theories and Applications
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: W EVE (4-7 PM) (E62-550)
______
Introduces fundamental behavioral theories of human decision making and demonstrates how they impact the design of management strategies and policies. Topics include prospect theory, reference-dependence preferences, loss aversion, ambiguity aversion, regret, inter-temporal preferences, social preferences, cognitive hierarchy, bounded rationality, and adaptive learning. Studies these concepts in a wide range of applications, including pricing, supply chain management, social welfare, marketing, contract design, sustainability, and e-commerce. Discusses experimental methodologies to identify and measure various preferences and phenomena, as well as mathematical models to capture them in decision making. Content updated from year to year to include state-of-the-art research.
K. Zheng
No textbook information available

15.799 Workshop in Operations Management
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
Lecture: M11.30-1 (E62-550)
______
Presentations by faculty, doctoral students, and guest speakers of ongoing research relating to current issues in operations management, including reports of research projects (proposed or in progress) and informal discussions of recent literature dealing with subjects of special interest to participants. Primarily for doctoral students.
Staff
No textbook information available

Marketing

15.809 Marketing Management
______

Graduate (Summer)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.732,15.810,15.812
______
Marketing is a rigorous, disciplined science that applies a reasoned framework to the selection of target markets and the optimization of marketing decisions. The subject has two parts: a tactical portion and a strategic portion. The strategic portion focuses on identifying target markets. The tactical portion reviews how firms optimize profits in their chosen markets. Tactical topics include pricing, promotion, channel and product issues. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
D. Simester
No textbook information available

15.810 Marketing Management
______

Graduate (Fall, Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.732,15.809,15.812
Lecture: MW1-2.30 (E62-233)
______
Develops skills in marketing analysis and planning, and introduces key marketing ideas and phenomena, such as how to deliver benefits to customers and marketing analytics. Presents a framework for marketing analysis and enhances problem solving and decision-making abilities in these areas. Material relevant to understanding, managing, and integrating marketing concepts in managerial situations, from entrepreneurial ventures to large multinational firms, and to consulting.
Consult J. R. Hauser, B. Wernerfelt
Textbooks (Fall 2016)

15.812 Marketing Management
______

Undergrad (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.732,15.809,15.810
______
Develops skills in marketing analysis and planning, and introduces key ideas and phenomena, such as how to deliver benefits to customers. Presents a framework for analysis and enhances problem solving and decision-making abilities in these areas. Material relevant to understanding, managing, and integrating marketing concepts in managerial situations, from entrepreneurial ventures to large multinational firms and to consulting. Primarily for undergraduate and non-MBA graduate students.
J. Zhang

15.818 Pricing
______

Graduate (Fall); first half of term
Prereq: None
Units: 3-0-3
Credit cannot also be received for15.726
Lecture: TR1-2.30 (E51-315) or TR2.30-4 (E51-315)
______
Framework for understanding pricing strategies and analytics, with emphasis on entrepreneurial pricing. Topics include economic value analysis, elasticities, customization, complementary products, pricing in platform markets, and anticipating competitive responses.
C. Tucker
Textbooks (Fall 2016)

15.821 Listening to the Customer
______

Graduate (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Introduction to soft consumer research methods, useful for getting quick customer input into decisions on product design and development, strategic positioning, advertising, and branding. Covers interview techniques, observational methods, voice of the customer, focus groups, and analyses suitable for qualitative data. Introduces new information-gathering methods in development at MIT.
D. Prelec

15.822 Strategic Market Measurement
______

Graduate (Spring); second half of term
Prereq: None
Units: 3-0-3
______
Project subject teaches students how to create, carry out, interpret, and analyze a market research questionnaire. Emphasis on discovering market structure and segmentation, but students can pursue other project applications. Includes a user-oriented treatment of multivariate analysis (factor analysis, multidimensional scaling, conjoint and cluster analysis).
D. Prelec

15.828 Product Management
______

Graduate (Spring)
Prereq: 15.810
Units: 3-1-5
______
Practical introduction to the process of product management. Covers the major phases of product management: opportunity identification (customer input, generating ideas, market definition), product design and positioning, pre-market testing and forecasting, launch marketing, and life-cycle management.
Staff

15.830 Enterprise Management Lab
______

Graduate (Fall, IAP)
Prereq: None.Coreq: 15.810, 15.761, or 15.900
Units: 3-0-3
Lecture: W EVE (4-7 PM) (E62-276)
______
Lays the foundation for the Enterprise Management (EM Lab)Track by developing students' ability to apply integrated management perspectives and practices in their roles within large organizations. Lectures, faculty mentors and cross-functional teams equip students with tools and knowledge to implement this track vision through classroom and project-based activities. Small teams of students deliver quality deliverables working on live integrative projects focused on marketing, operations, and/or Strategy sourced from large organizations, both for-profit and not-for-profit. Management guest speakers from Marketing, Operations and Strategy discuss their interrelated activities. The overall goal is to promote an integrated mindset towards viewing and addressing business issues. Students must register for both the fall term and IAP. Restricted to MBA students in EM Track.
S. Chatterjee
No textbook information available

15.833 Business-to-Business Marketing
______

Graduate (Fall); second half of term
Prereq: None
Units: 3-0-3
Begins Oct 31. Lecture: TR10-11.30 (E62-250)
______
Applies marketing concepts, analyses and tools used in business-to-business (B2B) marketing. Develops an understanding of customer value management as a strategy for delivering superior value to targeted business segments while maintaining equitable returns. Focuses on B2B pricing, brand building, web and technology facilitation of the supply chain, and customer relationship management. Underscores sales force management within the context of go-to-market strategy. Discusses ethical issues and various B2B contexts, such as products and services, for-profits and non-profits, and domestic and global markets. Emphasizes applications in technology and healthcare domains. Includes value-based pricing project, case studies, applied exercises, and readings.
S. Chatterjee
No textbook information available

15.834 Marketing Strategy
______

Graduate (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Uses case studies to introduce economic tools to look systematically at marketing strategy. Topics include how to identify and leverage customer-based competitive advantages and how to use them to develop new ones.
B. Wernerfelt

15.835 Entrepreneurial Marketing
______

Graduate (Spring); second half of term
Prereq: None
Units: 3-0-3
______
Provides foundational knowledge necessary to start and run a business. Discusses basic marketing theory as it applies to entrepreneurial firms. Includes guest speakers and final project.
B. Wernerfelt

15.838 Research Seminar in Marketing
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 15.810
Units: 3-0-6
Lecture: M1-4 (E62-526) +final
______
Seminar on current marketing literature and current research interests of faculty and students. Topics such as marketing models, consumer behavior, competitive strategy, marketing experimentation, and game theory. Restricted to doctoral students.
Consult D. Prelec
No textbook information available

15.839 Workshop in Marketing
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
Lecture: M4-5.30 (E62-550)
______
Presentations by faculty, doctoral students, and guest speakers of ongoing research relating to current issues in marketing. Topics: reports of research projects (proposed or in progress) and informal discussions of recent literature dealing with subjects of special interest to participants. Restricted to doctoral students.
Staff
No textbook information available

15.840-15.843 Seminar in Marketing
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 15.810
Units arranged
15.841: TBA.
15.842: TBA.
15.843: TBA.
______
Group study of current topics related to marketing.
Staff
15.841: No textbook information available
15.842: No textbook information available
15.843: No textbook information available

15.846 Branding
______

Graduate (Spring); second half of term
Prereq: 15.810
Units: 3-0-3
______
Provides a foundation for building, managing, and defending brands at various stages in the brand life cycle. Introduces the fundamentals of brand architecture and management relevant for B2C and B2B Marketing. Examples from a variety of industries cover topics that include brand co-creation, diffusion, imitation, and authenticity. Explores theory and practice using cases and academic research. Also looks at the development of leadership branding.
R. Gosline

15.847 Consumer Behavior
______

Graduate (Spring)
Prereq: 15.810
Units: 3-0-6
______
Examines models of consumer behavior and methods for its analysis and prediction. Focuses on theories developed in marketing, psychology, and other behavioral sciences, and their role in understanding consumer preferences and decision making. Reviews theories in the context of a variety of industry applications. Students apply theories to their own market research projects.
Staff

System Dynamics

15.871 Introduction to System Dynamics
______

Graduate (Fall, Spring); first half of term
Prereq: Permission of instructor
Units: 3-0-3
Credit cannot also be received for15.736
Ends Oct 21. Lecture: MW1-2.30 (E62-262) or MW2.30-4 (E62-276) or MW1-2.30 (E51-145) or MW2.30-4 (E51-325) Recitation: F10-11.30 (E62-250) or F2.30-4 (E51-315) or F8.30-10 (E62-250) or F2.30-4 (E51-315)
______
Introduction to systems thinking and system dynamics modeling applied to strategy, organizational change, and policy design. Students use simulation models, management flight simulators, and case studies to develop conceptual and modeling skills for the design and management of high-performance organizations in a dynamic world. Case studies of successful applications of system dynamics in growth strategy, management of technology, operations, supply chains, product development, and others. Principles for effective use of modeling in the real world. Meets with 15.8741 first half of term when offered concurrently. Expectations and evaluation criteria differ for students taking half-term graduate version; consult syllabus or instructor for specific details.
D. Keith, H. Rahmandad, N. Repenning, J. Sterman
Textbooks (Fall 2016)

15.872 System Dynamics II
______

Graduate (Fall, Spring); second half of term
Prereq: 15.871
Units: 3-0-3
Credit cannot also be received for15.737
Begins Oct 31. Lecture: MW1-2.30 (E62-262) or MW2.30-4 (E62-276) Recitation: F10-11.30 (E62-250) or F2.30-4 (E51-315)
______
Continuation of 15.871, emphasizing tools and methods needed to apply systems thinking and simulation modeling successfully in complex real-world settings. Uses simulation models, management flight simulators, and case studies to deepen the conceptual and modeling skills introduced in 15.871. Through models and case studies of successful applications students learn how to use qualitative and quantitative data to formulate and test models, and how to work effectively with senior executives to implement change successfully. Prerequisite for further work in the field. Meets with 15.8741 second half of term when offered concurrently. Expectations and evaluation criteria differ for students taking half-term graduate version; consult syllabus or instructor for specific details.
J. D. Sterman, H. Rahmandad, D. Keith
Textbooks (Fall 2016)

15.8741 System Dynamics for Business Policy
______

Undergrad (Fall, Spring)
Prereq: None
Units: 3-0-9
TBA.
______
Introduction to systems thinking and system dynamics modeling applied to strategy, organizational change, and policy design. Students use simulation models, management flight simulators, and case studies to develop conceptual and modeling skills for the design and management of high-performance organizations in a dynamic world. Case studies cover successful applications of system dynamics in growth strategy, management of technology, operations, supply chains, product development, and other areas. When offered concurrently, meets with 15.871 first half of term and with 15.872 second half of term. Expectations and evaluation criteria differ for students taking the half-term graduate subjects; consult syllabus or instructor for specific details.
J. Sterman, H. Rahmandad, D. Keith
No textbook information available

15.875 Applications of System Dynamics
______

Graduate (Spring) Can be repeated for credit
Prereq: 15.872
Units: 3-0-6
______
Explores how system dynamics can help organizations achieve important goals. Student teams pair with clients to tackle a pressing issue framed by the client and its partners. In interactive classroom sessions, and via client engagement, students learn modeling and consulting skills they need to be effective. Focuses on gaining practical insight from system dynamics and its application across a wide range of organizations and challenges.
Consult J. D. Sterman

15.878 Capstone Seminar in Sustainability
______

Graduate (Spring); second half of term
Prereq: 15.913
Units: 3-0-3
______
Provides an opportunity for students to synthesize their coursework and experiences in sustainability. Involves deep intellectual exploration of fundamental debates in sustainability through classic and current readings that are essential for working in the field. Students link ideas to practice through an analysis of the industry they plan to enter after graduation.
M. Amengual

15.879 Research Seminar in System Dynamics
______

Graduate (Spring) Can be repeated for credit
Prereq: 15.872 and permission of instructor
Units: 3-0-9
______
Doctoral level seminar in system dynamics modeling, with a focus on social, economic and technical systems. Covers classic works in dynamic modeling from various disciplines and current research problems and papers. Participants critique the theories and models, often including replication, testing, and improvement of various models, and lead class discussion. Topics vary from year to year.
Consult D. Keith, J. Sterman

Strategic Management

15.900 Competitive Strategy
______

Graduate (Fall, Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.9001
Lecture: MW8.30-10 (E51-345) or MW10-11.30 (E51-345)
______
Explores a wide range of strategic problems, focusing particularly on the sources of competitive advantage and the interaction between industry structure and organizational capabilities. Introduces a wide variety of modern strategy frameworks and methodologies. Builds upon and integrates material from core topics, such as economics and organizational processes. Students taking graduate version complete additional assignments. Meets with 15.9001 when offered concurrently.
D. Sull, N. Thompson, A. Kacperczyk
No required or recommended textbooks

15.9001 Competitive Strategy
______

Undergrad (Spring)
Prereq: None
Units: 3-0-6
Credit cannot also be received for15.900
______
Explores a wide range of strategic problems, focusing particularly on the sources of competitive advantage and the interaction between industry structure and organizational capabilities. Introduces a wide variety of modern strategy frameworks and methodologies. Builds upon and integrates material from core topics, such as economics and organizational processes. Students taking graduate version complete additional assignments. Meets with 15.900 when offered concurrently.
D. Sull, N. Thompson, A. Kacperczyk

15.902 Competitive Strategy
______

Graduate (Spring); first half of term
Prereq: Permission of instructor
Units: 2-0-4
Credit cannot also be received for15.714
______
Focuses on developing skills and applying frameworks for the conduct of competitive and corporate strategy. Develops tools from earlier core courses, especially those from Strategic Marketing and Organizational Processes, and Economics. Emphasis is placed on the role of strategic commitments, social networks, strategic coherence, and adapting to environmental and technological change. Restricted to MIT Sloan Fellows in Innovation and Global Leadership.
E. Zuckerman

15.903 Managing the Modern Organization: Organizational Economics and Corporate Strategy
______

Graduate (Spring); first half of term
Prereq: 15.010 or 15.311
Units: 3-0-3
______
Focuses on how managers build and manage complex organizations to achieve strategic goals. Develops theoretical frameworks that build on 15.010 and 15.311. Applies these frameworks to corporate strategy (i.e., the design and management of the multi-business firm) and extended enterprises (i.e., the design and management of multi-firm structures such as supply chains, alliances, joint ventures, and networks).
R. Gibbons

15.904 Advanced Strategic Management
______

Graduate (Spring); second half of term
Prereq: 15.900, or permission of instructor
Units: 3-0-3
Subject Cancelled Subject Cancelled
______
Builds on 15.900 and 15.902 to explore key concepts that have shaped the field of strategic management and strategy consulting over the past several decades. Uses lectures, readings, case studies, and videos to review the evolution of strategy teaching, research, and practice; the role of randomness in strategic outcomes; the difference between strategic thinking versus planning; and enduring principles related to competitive advantage. Key themes include the role of platform strategies and services, as well as capabilities, pull mechanisms, economies of scope, and flexibility, with examples from a variety of industries. Develops an understanding of what has made some firms successful in the past as well as what managers can do to compete in an uncertain future.
M. Cusumano

15.905 Technology Strategy
______

Graduate (Spring)
Prereq: None
Units: 3-0-9
______
Provides a series of strategic frameworks for managing high-technology businesses. Emphasis on the development and application of conceptual models which clarify the interactions between competition, patterns of technological and market change, and the structure and development of internal firm capabilities.
J. Utterback

15.910 Innovation Strategy
______

Graduate (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Establishes a solid foundation for students interested in formulating and executing a strategy for a technology-intensive business. Clarifies the interactions among competition, patterns of technological and market change, and the development of internal firm capabilities. Topics include appropriating the returns from innovation, the role of intellectual property, cooperative and open innovation, organization of R&D activities inside the firm, and multi-sided platform strategy. Key conceptual frameworks are linked to applications in a variety of industry and case settings.
B. Roin

15.911 Entrepreneurial Strategy
______

Graduate (Spring); second half of term
Prereq: None
Units: 4-0-2
______
Provides a deep understanding of the core strategic choices facing start-up innovators, as well as a synthetic framework for the development and implementation of entrepreneurial strategy in dynamic environments. Identifies the key choices entrepreneurs make to take advantage of opportunity and the logic of particular strategic commitments that allow entrepreneurs to establish competitive advantage.
S. Stern

15.912 Strategic Management of Innovation and Entrepreneurship
______

Graduate (Spring); second half of term
Prereq: 15.910, 15.911, or permission of instructor
Units: 3-0-3
______
Provides a series of strategic frameworks for managing high-technology businesses with a particular focus on innovation and entrepreneurship, especially as it builds upon patterns of technological and market change, prior research on product development and new ventures, and the structure and development of organizational capabilities. Includes case analyses and simulations, as well as independent readings drawn from research in technological innovation, entrepreneurial management, and organizational theory.
Staff

15.913 Strategies for Sustainable Business
______

Graduate (Spring); first half of term
Prereq: None
Units: 3-0-3
______
Develops a pragmatic, action-oriented approach to sustainability: the alignment between healthy businesses, healthy environments, healthy societies, and an economy that meets human needs. In-class simulations and role-playing provide a robust foundation for understanding sustainability challenges. Cases analyze innovative strategies for sustainable businesses and organizations. Class discussions explore how sustainability is changing existing business models and market structures, how to develop sustainable management practices, and how firms can implement those practices successfully.
M. Amengual, J. Jay, J. Sterman

15.914 Competitive Dynamics and Strategy: Winning in Technology Markets
______

Graduate (Spring)
Prereq: 15.872; 15.369, 15.567, 15.900, or 15.902
Units: 2-0-7
______
Focuses on competitive strategy in technology-driven markets. Students acquire a portfolio of models of the signature dynamics in these markets and use the models in projects with participating companies to analyze technology markets, formulate competitive strategies, and illuminate the challenges of execution. Addresses issues critical for both established incumbents and new market entrants. Restricted to graduate students.
H. B. Weil

15.915 Laboratory for Sustainable Business
______

Graduate (Spring)
Prereq: 15.913
Units: 4-0-2
______
Provides students with the opportunity to apply the concepts, theories, and tools of sustainability by working with a host organization on a real management project during the semester. Classroom lectures and simulations complement project work to give greater depth in techniques for managing sustainability. Topics include start-up dynamics, certification programs, evaluating the environmental impact of products and services, and leveraging consumers to advance sustainability.
M. Amengual, J. Jay, J. Sterman

15.928 The Sociology of Strategy
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 15.342
Units: 3-0-9
______
Doctoral seminar in theory building for social scientists interested in economic sociology, organization theory, strategic management, and related fields. Builds skills for developing social scientific theory. Focuses on assessing and developing the relevance of sociological research for key questions in strategy research: what explains the relative performance of firms and the variety of their strategies for achieving performance. Students also develop skills in evaluating academic research in this area. Restricted to doctoral students.
E. Zuckerman

15.929 Identity and Action
______

Graduate (Spring)
Prereq: 15.342
Units: 3-0-9
______
Doctoral seminar in theory building for social scientists. Primary goal is to build skills for developing social scientific theory. Secondary goals are to review and integrate a broad array of ideas concerning the foundations of identity and its relation to action, and to suggest how such issues relate to a broader set of questions in the social sciences. Students learn that any account of action is based on ascribing desires, beliefs, and opportunities to specific actors, but such actors cannot be easily explained except as a result of action by prior actors. The focus of this course is around developing this paradox and providing a foundation for resolving it. Restricted to doctoral students.
E. Zuckerman

15.933 Strategic Opportunities in Energy
______

Graduate (Fall); first half of term
Prereq: 15.900 or permission of instructor
Units: 4-0-2
Ends Oct 21. Lecture: MW EVE (4-6 PM) (E62-223)
______
Introduces the energy system in terms of sources and uses, market characteristics, and key metrics. Provides frameworks for understanding the structure and dynamics of the sector and the drivers of the energy future. Opportunities resulting from demand growth, supply challenges, environmental constraints, security of supply, technology breakthroughs, and regulation are analyzed from the perspectives of both established players and entrepreneurs. Student teams engage in projects that evaluate a segment of the energy landscape and develop a strategic prospectus for a new business opportunity.
H. B. Weil, A. J. M. Meggs
No textbook information available

15.941[J] Leadership in Real Estate
______

Graduate (Fall); first half of term
(Same subject as11.430[J])
Prereq: None
Units: 3-0-3
Ends Oct 21. Lecture: MW10.30-12 (9-357)
______
Designed to help students deepen their understanding of leadership and increase self-awareness. They examine authentic leadership styles and create goals and a learning plan to develop their capabilities. They also participate in activities to strengthen their "leadership presence" - the ability to authentically connect with people's hearts and minds. Students converse with leaders to learn from their insights, experiences, and advice. Limited to 15.
G. Schuck
Textbooks (Fall 2016)

15.949 Seminar in Strategy
______

Graduate (Fall) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Opportunity for group study by graduate students on current topics related to strategy.
Consult E. Zuckerman
No textbook information available

Special Subjects

15.S01 Special Seminar in Management
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: F8.30-12 (E51-145, E51-149, E51-315, E51-325, E51-345, E51-395)
______
No textbook information available

15.S02 Special Seminar in Management
______

Graduate (Fall, IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: R EVE (4-7 PM) (E62-250)
______
No textbook information available

15.S03 Special Seminar in Management
______

Graduate (Fall, IAP, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Ends Oct 21. Lecture: W1-4 (E62-250)
______
No textbook information available

15.S04 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: MW2.30-4 (E51-145) +final
______
Textbooks (Summer 2016); No required or recommended textbooks (Fall 2016)

15.S05 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit; second half of term
Prereq: Permission of instructor
Units arranged
Lecture: TR4-5.30 (E51-395)
______
No textbook information available

15.S06 Special Seminar in Management
______

Graduate (Fall, Spring, Summer) Can be repeated for credit; second half of term
Prereq: Permission of instructor
Units arranged
Ends Oct 21. Lecture: M4-5.30 (E51-149) or W4-5.30 (E51-149)
______
No textbook information available

15.S07 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit; second half of term
Prereq: Permission of instructor
Units arranged
Begins Oct 31. Lecture: MW8.30-10 (E51-145) or MW10-11.30 (E51-145) Recitation: F8.30-10 (E51-335) or F10-11.30 (E51-335)
______
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

15.S08 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit; first half of term
Prereq: Permission of instructor
Units arranged
Lecture: T EVE (5-8 PM) (E62-221)
______
Staff
No textbook information available

15.S09 Special Seminar in Management
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: T EVE (5.30-7.30 PM) or TBA
______
Textbooks (Fall 2016)

15.S10-15.S12 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit; second half of term
Prereq: Permission of instructor
Units arranged
15.S10: TBA.
15.S11: Lecture: M1.30-3 (E62-350)
15.S12: TBA.
______
15.S10: No textbook information available
15.S11: No textbook information available
15.S12: No textbook information available

15.S13, 15.S14 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit; first half of term
Prereq: Permission of instructor
Units arranged
15.S13: Ends Oct 21. Lecture: M EVE (6-9 PM) (E51-345)
15.S14: Ends Oct 21. Lecture: M8.30-10 (E51-395)
______
15.S13: No textbook information available
15.S14: No textbook information available

15.S15, 15.S16 Special Seminar in Management
______

Graduate (Fall, IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
15.S15: Lecture: F12-2 (E51-063)
15.S16: TBA.
______
15.S15: No textbook information available
15.S16: No textbook information available

15.S17 Special Seminar in Management
______

Graduate (Fall, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
Lecture: R EVE (4-7 PM) (E62-250)
______
Textbooks (Summer 2016); No textbook information available (Fall 2016)

15.S18, 15.S19 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
15.S18: Lecture: MW10-11.30 (E51-151) +final
15.S19: TBA.
______
15.S18: No required or recommended textbooks
15.S19: No textbook information available

15.S20-15.S26 Special Seminar in Management
______

Graduate (IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
15.S20: Lecture: W1-2.30 (E62-346)
15.S22: TBA.
______
Group study of current topics related to management not otherwise included in curriculum. Coursework may continue into the following term.
Consult Sloan Educational Services
15.S20: No textbook information available
15.S21: No textbook information available
15.S22: No textbook information available
15.S24: Textbooks (Summer 2016)

15.S30-15.S33 Special Distance Learning Seminar in Management
______

Graduate (Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
15.S31: TBA.
15.S32: TBA.
______
15.S31: No textbook information available
15.S32: No textbook information available
15.S33: No textbook information available

15.S35-15.S38 Special Distance Learning Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
15.S35: TBA.
15.S36: TBA.
15.S37: TBA.
15.S38: TBA.
______
Group study through distance learning on current topics related to management.
Consult Sloan Educational Services
15.S35: No textbook information available
15.S36: No textbook information available
15.S37: No textbook information available
15.S38: No textbook information available

15.S40, 15.S41 Special Seminar in Management
______

Undergrad (IAP) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
15.S40: TBA.
______
15.S40: No textbook information available

15.S42-15.S47 Special Seminar in Management
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged
15.S42: Lecture: TR1-2.30 (56-154)
15.S43: TBA.
15.S44: TBA.
15.S45: TBA.
15.S46: TBA.
15.S47: TBA.
______
15.S42: No textbook information available
15.S43: No textbook information available
15.S44: No textbook information available
15.S45: No textbook information available
15.S46: No textbook information available
15.S47: No textbook information available

15.S50-15.S54 Special Seminar in Management
______

Graduate (Fall, IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
15.S50: TBA.
15.S53: TBA.
15.S54: TBA.
______
15.S50: No textbook information available
15.S53: No textbook information available
15.S54: No textbook information available

15.S55-15.S59 Special Seminar in Management
______

Graduate (IAP) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
15.S55: TBA.
______
15.S55: No textbook information available

15.S60-15.S65 Special Seminar in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
15.S61: TBA.
15.S63: TBA.
15.S64: TBA.
15.S65: TBA.
______
15.S61: No textbook information available
15.S63: No textbook information available
15.S64: No textbook information available
15.S65: No textbook information available

15.S66-15.S69 Special Seminar in Management
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
15.S66: TBA.
15.S67: Lecture: W9-12 (E51-390)
______
15.S66: No textbook information available
15.S67: No textbook information available
15.S68: No textbook information available

15.S70-15.S75 Special Seminar in Management
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
15.S72: Lecture: TR4-5.30 (E51-335) Recitation: F12 (E51-335) +final
15.S73: TBA.
15.S74: TBA.
15.S75: TBA.
______
Group study of current topics related to management not otherwise included in curriculum.
Consult Sloan Educational Services
15.S72: No textbook information available
15.S73: Textbooks (Fall 2016)
15.S74: No textbook information available
15.S75: No textbook information available

Thesis, Research, and Practice

15.UR Undergraduate Research in Management
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually

15.URG Undergraduate Studies in Management
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Participation in the work of a research group which includes such activities as independent study of the literature, direct involvement in the group's research (commensurate with the student's skills and preparation), or project work under an individual faculty member possibly extending over more than one term. Admission by arrangement with individual faculty member. Requires written project report.
J. S. Carroll
Textbooks arranged individually

15.950 Independent Study in Management
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
No textbook information available

15.951 Independent Study in Management
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Advanced work, special investigation or application of a management topic, on an individual basis, under faculty supervision. May include readings, conferences, laboratory and fieldwork, and reports. Projects require prior approval, as well as a written proposal and a final report.
M. Hanlon
No textbook information available

15.952 Curricular Practical Training
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units: 0-1-0 [P/D/F]
TBA.
______
For Course 15 undergraduate students participating in management curriculum-related off-campus work experiences. Students must have an employment offer from a company or organization and must find a Sloan faculty supervisor before enrolling. Consult Sloan Undergraduate Education Office
M. Hanlon
No textbook information available

15.960 Independent Study in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
No textbook information available

15.961 Independent Study in Management
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Advanced work, special investigation or application of a management topic, on an individual basis, under faculty supervision. May include readings, conferences, laboratory and fieldwork, and reports. Projects require prior approval, as well as a written proposal and a final report.
Consult Sloan Educational Services
No textbook information available

15.962 Pre-Thesis Research
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Pre-thesis research conducted under faculty supervision; advance approval of project proposal required. Restricted to PhD students.
Consult H. Ross
No textbook information available

15.998 Independent Group Study in Action Learning
______

Graduate (Fall, IAP, Spring, Summer)
Prereq: None
Units arranged
TBA.
______
Team-based opportunities for application management tools, under faculty supervision, on dynamic projects that provide a wide array of operational challenges facing organizations around the world. May include travel to on-site locales. Projects require prior approval, as well as a written proposal and a final report.
Consult T. Walor
No textbook information available

15.999 Curricular Practical Training (CPT)
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
15.999: TBA.
______
Students participate in off-campus work or internship experience and apply topics of management and/or culture to their experience. Requirements include mandatory attendance at one workshop and a written deliverable. Students must have a formal employment offer prior to enrolling. Restricted to MIT Sloan students who have been in legal F1 status for nine consecutive months and who wish to work in the United States in an area related to their field of study. Additional restrictions may apply.
Consult Sloan Educational Services
15.999: No textbook information available

15.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Research and writing of thesis; to be arranged by the student with supervising committee.
Consult Sloan Educational Services
Textbooks arranged individually


left arrow|15.00-15.299|15.30-15.699|15.70-15.999 plus UROP and Thesis|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 16: Aeronautics and Astronautics
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Course 16: Aeronautics and Astronautics
Fall 2016


16.00A[J] Fundamentals of Engineering Design: Explore Space, Sea and Earth
______

Undergrad (Spring)
Not offered regularly; consult department
(Same subject as2.00A[J])
Prereq: Physics I (GIR), Calculus I (GIR)
Units: 3-3-3
______
Student teams formulate and complete space/earth/ocean exploration-based design projects with weekly milestones. Introduces core engineering themes, principles, and modes of thinking. Specialized learning modules enable teams to focus on the knowledge required to complete their projects, such as machine elements, electronics, design process, visualization and communication. Includes exercises in written and oral communication and team building. Examples of projects include surveying a lake for millfoil, from a remote controlled aircraft, and then sending out robotic harvesters to clear the invasive growth; and exploration to search for the evidence of life on a moon of Jupiter, with scientists participating through teleoperation and supervisory control of robots. Enrollment limited; preference to freshmen.
A. H. Techet, D. Newman

16.00 Introduction to Aerospace and Design
______

Undergrad (Spring)
Prereq: None
Units: 3-1-5
URL: http://web.mit.edu/16.00/
______
The fundamental concepts and approaches of aerospace engineering are highlighted through lectures on aeronautics, astronautics, and design. Active learning aerospace modules make use of information technology. Student teams are immersed in a hands-on, lighter-than-air (LTA) vehicle design project where they design, build, and fly radio-controlled LTA vehicles. The connections between theory and practice are realized in the design exercises. Required design reviews precede the LTA race competition. The performance, weight, and principle characteristics of the LTA vehicles are estimated and illustrated using physics, mathematics, and chemistry known to freshmen, the emphasis being on the application of this knowledge to aerospace engineering and design rather than on exposure to new science and mathematics. Includes exercises in written and oral communication and team building.
J. A. Hoffman, R. J. Hansman

16.001 Unified Engineering: Materials and Structures
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR);Coreq: 16.002; 18.03 or 18.034
Units: 5-1-6
TR classroom is 32-144. Lecture: MRF9,T10 (32-141) Lab: TBA Recitation: W9 (32-141) +final
______
Presents fundamental principles and methods of materials and structures for aerospace engineering, and engineering analysis and design concepts applied to aerospace systems. Topics include statics; analysis of trusses; analysis of statically determinate and indeterminate systems; stress-strain behavior of materials; analysis of beam bending, buckling, and torsion; material and structural failure, including plasticity, fracture, fatigue, and their physical causes. Experiential lab and aerospace system projects provide additional aerospace context.
R. Radovitzky, D. L. Darmofal
Textbooks (Fall 2016)

16.002 Unified Engineering: Signals and Systems
______

Undergrad (Fall)
Prereq: Calculus II (GIR);Coreq: 16.001; Physics II (GIR); 18.03 or 18.034
Units: 5-1-6
TR classroom is 32-144. Lecture: MTRF10 (32-141) Lab: TBA Recitation: W10 (32-141) +final
______
Presents fundamental principles and methods of signals and systems for aerospace engineering, and engineering analysis and design concepts applied to aerospace systems. Topics include linear and time invariant systems; convolution; transform analysis; and modulation, filtering, and sampling. Experiential lab and aerospace system projects provide additional aerospace context.
K. E. Willcox, D. L. Darmofal
Textbooks (Fall 2016)

16.003 Unified Engineering: Fluid Dynamics
______

Undergrad (Spring)
Prereq: Calculus II (GIR); Physics II (GIR);18.03 or 18.034;Coreq: 16.004
Units: 5-1-6
______
Presents fundamental principles and methods of fluid dynamics for aerospace engineering, and engineering analysis and design concepts applied to aerospace systems. Topics include aircraft and aerodynamic performance, conservation laws for fluid flows, quasi-one-dimensional compressible flows, shock and expansion waves, streamline curvature, potential flow modeling, an introduction to three-dimensional wings and induced drag. Experiential lab and aerospace system projects provide additional aerospace context.
D. L. Darmofal

16.004 Unified Engineering: Thermodynamics
______

Undergrad (Spring)
Prereq: Calculus II (GIR); Physics II (GIR);18.03 or 18.034;Coreq: 16.003; Chemistry (GIR)
Units: 5-1-6
______
Presents fundamental principles and methods of thermodynamics for aerospace engineering, and engineering analysis and design concepts applied to aerospace systems. Topics include thermodynamic state of a system, forms of energy, work, heat, the first law of thermodynamics, heat engines, reversible and irreversible processes, entropy and the second law of thermodynamics, ideal and non-ideal cycle analysis, two-phase systems, and introductions to thermochemistry and heat transfer. Experiential lab and aerospace system projects provide additional aerospace context.
Z. S. Spakovszky, D. L. Darmofal

Core Undergraduate Subjects

16.06 Principles of Automatic Control
______

Undergrad (Fall)
Prereq: 16.002; 16.003 or 16.004
Units: 3-1-8
Lecture: MW1 (32-155) Lab: F1 (33-319) or F2 (33-319) Recitation: T11 (37-212) or T2 (37-212) +final
______
Introduction to design of feedback control systems. Properties and advantages of feedback systems. Time-domain and frequency-domain performance measures. Stability and degree of stability. Root locus method, Nyquist criterion, frequency-domain design, and some state space methods. Strong emphasis on the synthesis of classical controllers. Application to a variety of aerospace systems. Hands-on experiments using simple robotic systems.
J. P. How
No required or recommended textbooks

16.07 Dynamics
______

Undergrad (Fall)
Prereq: 16.001 or 16.002; 16.003 or 16.004
Units: 4-0-8
Lecture: MWF11 (37-212) Recitation: R10 (33-419) or R11 (33-418) +final
______
Fundamentals of Newtonian mechanics. Kinematics, particle dynamics, motion relative to accelerated reference frames, work and energy, impulse and momentum, systems of particles and rigid body dynamics. Applications to aerospace engineering including introductory topics in orbital mechanics, flight dynamics, inertial navigation and attitude dynamics.
W. W. Hoburg
No required or recommended textbooks

16.09 Statistics and Probability
______

Undergrad (Spring)
Prereq: Calculus II (GIR)
Units: 4-0-8
______
Introduction to statistics and probability with applications to aerospace engineering. Covers essential topics, such as sample space, discrete and continuous random variables, probability distributions, joint and conditional distributions, expectation, transformation of random variables, limit theorems, estimation theory, hypothesis testing, confidence intervals, statistical tests, and regression.
L. A. Stirling

Mechanics and Physics of Fluids

16.100 Aerodynamics
______

Undergrad (Fall)
Prereq: 16.003, 16.004
Units: 3-1-8
F10 in room 33-419. Lecture: MWF10 (4-231) Lab: T10 (33-319) or T1 (33-319)
______
Extends fluid mechanic concepts from Unified Engineering to aerodynamic performance of wings and bodies in sub/supersonic regimes. Addresses themes such as subsonic potential flows, including source/vortex panel methods; viscous flows, including laminar and turbulent boundary layers; aerodynamics of airfoils and wings, including thin airfoil theory, lifting line theory, and panel method/interacting boundary layer methods; and supersonic and hypersonic airfoil theory. Material may vary from year to year depending upon focus of design problem.
Y. M. Marzouk
Textbooks (Fall 2016)

16.101 Topics in Fluids and Propulsion
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of department
Units arranged
TBA.
______
Provides credit for work on material in fluids or propulsion outside of regularly scheduled subjects. Intended for study abroad under either the department's Year Abroad Program or the Cambridge-MIT Exchange Program. Credit may be used to satisfy specific SB degree requirements. Requires prior approval. Consult department.
N. Roy
No textbook information available

16.110 Flight Vehicle Aerodynamics
______

Graduate (Fall)
Prereq: 16.100 or permission of instructor
Units: 3-1-8
Lecture: MWF1 (33-418)
______
Aerodynamic analysis of flight vehicles using analytical, numerical, and experimental techniques separately and in combination. Matched asymptotic expansions. Farfield behavior. Finite wing theory. Trefftz-plane analysis. Laminar and turbulent boundary layers. Slender body theory. Calculation and measurement of drag components. Aerodynamic stability derivatives.
D. L. Darmofal
Textbooks (Fall 2016)

16.120 Compressible Internal Flow and Aeroacoustics
______

Graduate (Spring)
Prereq: 2.25 or permission of instructor
Units: 3-0-9
______
Internal compressible flow and fundamentals of acoustics and aerodynamic sound with applications in turbomachinery and propulsion systems. Quasi-one-dimensional compressible flow (channel flow) and extensions, including effects of shock waves, friction, energy and mass addition, swirl, and flow non-uniformity. Unsteady compressible flow, theory of sound, sources of sound and wave propagation, Lighthill's acoustic analogy, and characterization and estimation of noise sources encountered in turbomachinery and aircraft applications.
E. M. Greitzer, W. L. Harris

16.121 Analytical Subsonic Aerodynamics
(New)
______

Graduate (Fall); partial term
Prereq: 2.25, 18.085, or permission of instructor
Units: 3-0-3
Begins Oct 24. Lecture: MW9.30-11 (33-422)
______
Analysis of external inviscid, subsonic, flow over aerodynamic thin airfoils and slender lifting bodies. Analyses formulated using singular perturbation and multiple scale methods. Linearized theory. Similarity. Rayleigh-Janzen method. Prandtl-Glauert method. Göthert similarity rule. Subsonic flow past a wave-shaped wall.
W. L. Harris
No required or recommended textbooks

16.122 Analytical Subsonic Aerodynamics
______

Graduate (Spring); partial term
Prereq: 2.25, 18.085, or permission of instructor
Units: 3-0-3
______
External compressible subsonic flows for aerodynamic applications. Two and three dimensional flows. Flows with axial symmetry. Flows past a wave-shaped wall. Slender aerodynamic bodies. Similarity rules and higher approximations for similarity rules. Solutions obtained by regular and singular perturbation methods. Comparisons of experimental, computational and analytical results.
W. L. Harris

16.13 Aerodynamics of Viscous Fluids
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 16.100, 16.110, or permission of instructor
Units: 3-0-9
______
Boundary layers as rational approximations to the solutions of exact equations of fluid motion. Physical parameters influencing laminar and turbulent aerodynamic flows and transition. Effects of compressibility, heat conduction, and frame rotation. Influence of boundary layers on outer potential flow and associated stall and drag mechanisms. Numerical solution techniques and exercises.
M. Drela

Materials and Structures

16.20 Structural Mechanics
______

Undergrad (Spring)
Prereq: 16.001
Units: 5-0-7
URL: http://web.mit.edu/16.20/www/
______
Applies solid mechanics to analysis of high-technology structures. Structural design considerations. Review of three-dimensional elasticity theory; stress, strain, anisotropic materials, and heating effects. Two-dimensional plane stress and plane strain problems. Torsion theory for arbitrary sections. Bending of unsymmetrical section and mixed material beams. Bending, shear, and torsion of thin-wall shell beams. Buckling of columns and stability phenomena. Introduction to structural dynamics. Exercises in the design of general and aerospace structures.
Staff

16.201 Topics in Materials and Structures
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of department
Units arranged
TBA.
______
Provides credit for work in materials and structures outside of regularly scheduled subjects. Intended for study abroad under either the department's Year Abroad Program or the Cambridge-MIT Exchange Program. Credit may be used to satisfy specific SB degree requirements. Requires prior approval. Consult department.
N. Roy
No textbook information available

16.202 Manufacturing with Advanced Composite Materials
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: None
Units: 1-3-2
Subject Cancelled Subject Cancelled
______
Introduces the methods used to manufacture parts made of advanced composite materials with work in the Technology Laboratory for Advanced Composites. Students gain hands-on experience by fabricating, machining, instrumenting, and testing graphite/epoxy specimens. Students also design, build, and test a composite structure as part of a design contest. Lectures supplement laboratory sessions with background information on the nature of composites, curing, composite machining, secondary bonding, and the testing of composites.
P. A. Lagace

16.221[J] Structural Dynamics and Vibrations
______

Graduate (Fall)
(Same subject as1.581[J],2.060[J])
(Subject meets with1.058)
Prereq: Permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/16.221/www/
Lecture: MWF10 (1-390) Recitation: W4 (1-246)
______
Single- and multiple-degree-of-freedom vibration problems, using matrix formulation and normal mode superposition methods. Time and frequency domain solution techniques including convolution and Fourier transforms. Applications to vibration isolation, damping treatment, and dynamic absorbers. Analysis of continuous systems by exact and approximate methods. Applications to buildings, ships, aircraft and offshore structures. Vibration measurement and analysis techniques. Students should possess basic knowledge in structural mechanics and in linear algebra. Students taking graduate version complete additional assignments.
E. Kausel, J. K. Vandiver
No textbook information available

16.223[J] Mechanics of Heterogeneous Materials
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as2.076[J])
Prereq: 2.002, 3.032, 16.20, or permission of instructor
Units: 3-0-9
______
Mechanical behavior of heterogeneous materials such as thin-film microelectro- mechanical systems (MEMS) materials and advanced filamentary composites, with particular emphasis on laminated structural configurations. Anisotropic and crystallographic elasticity formulations. Structure, properties and mechanics of constituents such as films, substrates, active materials, fibers, and matrices including nano- and micro-scale constituents. Effective properties from constituent properties. Classical laminated plate theory for modeling structural behavior including extrinsic and intrinsic strains and stresses such as environmental effects. Introduction to buckling of plates and nonlinear (deformations) plate theory. Other issues in modeling heterogeneous materials such as fracture/failure of laminated structures.
B. L. Wardle, S-G. Kim

16.225[J] Computational Mechanics of Materials
______

Graduate (Fall)
Not offered regularly; consult department
(Same subject as 2.099[J])
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Formulation of numerical (finite element) methods for the analysis of the nonlinear continuum response of materials. The range of material behavior considered includes finite deformation elasticity and inelasticity. Numerical formulation and algorithms include variational formulation and variational constitutive updates; finite element discretization; constrained problems; time discretization and convergence analysis. Strong emphasis on the (parallel) computer implementation of algorithms in programming assignments. The application to real engineering applications and problems in engineering science are stressed throughout. Experience in either C++, C, or Fortran required.
R. Radovitzky

16.230[J] Plates and Shells: Static and Dynamic Analysis
______

Graduate (Spring)
(Same subject as2.081[J])
Prereq: 2.071, 2.080, or permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/16.230/home.html
______
Stress-strain relations for plate and shell elements. Differential equations of equilibrium. Energy methods and approximate solutions. Bending and buckling of rectangular plates. Post-buckling and ultimate strength of cold formed sections and typical stiffened panels used in aerospace, civil, and mechanical engineering; offshore technology; and ship building. Geometry of curved surfaces. General theory of elastic, axisymmetric shells and their equilibrium equations. Buckling, crushing and bending strength of cylindrical shells with applications. Propagation of 1-D elastic waves in rods, geometrical and material dispersion. Plane, Rayleigh surface, and 3-D waves. 1-D plastic waves. Response of plates and shells to high-intensity loads. Dynamic plasticity and fracture. Application to crashworthiness and impact loading of structures.
T. Sapsis

Information and Control Engineering

16.30 Feedback Control Systems
______

Undergrad (Fall)
(Subject meets with16.31)
Prereq: 16.06 or 6.302
Units: 4-1-7
Lecture: MWF11 (4-237) Lab: TBA Recitation: F1 (33-419) +final
______
Reviews classical control design using root locus and frequency domain methods (Nyquist diagrams and Bode plots). Studies state-space representation of dynamic systems, including model realizations, controllability, and observability. Introduces the state-space approach to control system analysis and synthesis, including full state feedback using pole placement, state estimation, and the design of dynamic control laws. Also covers performance limitations and robustness. Extensive use of computer-aided control design tools. Applications to various aerospace systems including navigation, guidance, and control of vehicles. Students taking the graduate version complete additional assignments.
S. Karaman
Textbooks (Fall 2016)

16.301 Topics in Control, Dynamics, and Automation
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of department
Units arranged
TBA.
______
Provides credit for work on material in control and/or dynamics and/or automation outside of regularly scheduled subjects. Intended for study abroad under either the department's Year Abroad Program or the Cambridge-MIT Exchange Program. Credit may be used to satisfy specific SB degree requirements. Requires prior approval. Consult department.
N. Roy
No textbook information available

16.31 Feedback Control Systems
______

Graduate (Fall)
(Subject meets with16.30)
Prereq: 16.06 or 6.302
Units: 3-1-8
Lecture: MWF11 (4-237) Lab: TBA +final
______
Graduate-level version of 16.30; see description under 16.30. Includes additional homework questions, laboratory experiments, and a term project beyond 16.30 with a particular focus on the material associated with state-space realizations of MIMO transfer function (matrices); MIMO zeros, controllability, and observability; stochastic processes and estimation; limitations on performance; design and analysis of dynamic output feedback controllers; and robustness of multivariable control systems.
S. Karaman
Textbooks (Fall 2016)

16.322 Stochastic Estimation and Control
______

Graduate (Fall)
Prereq: 16.31; 6.041B, 6.431B, or 16.09
Units: 3-0-9
Lecture: MW1-2.30 (33-319)
______
Estimation and control of dynamic systems. Brief review of probability and random variables. Classical and state-space descriptions of random processes and their propagation through linear systems. Frequency domain design of filters and compensators. The Kalman filter to estimate the states of dynamic systems. Conditions for stability of the filter equations.
N. Roy
Textbooks (Fall 2016)

16.323 Principles of Optimal Control
______

Graduate (Spring)
Prereq: 18.085, 16.31
Units: 3-0-9
______
Studies basic optimization and the principles of optimal control. Considers deterministic and stochastic problems for both discrete and continuous systems. Solution methods include numerical search algorithms, model predictive control, dynamic programming, variational calculus, and approaches based on Pontryagin's maximum principle. Includes many examples and applications of the theory.
S. R. Hall, J. P. How

16.333 Aircraft Stability and Control
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 16.31 or permission of instructor
Units: 3-0-9
______
Brief review of applied aerodynamics and modern approaches in aircraft stability and control. Static stability and trim. Stability derivatives and characteristic longitudinal and lateral-directional motions. Physical effects of wing, fuselage, and tail on aircraft motion. Flight vehicle stabilization by classical and modern control techniques. Time and frequency domain analysis of control system performance. Human pilot models and pilot-in-the-loop control with applications. V/STOL stability, dynamics, and control during transition from hover to forward flight. Parameter sensitivity and handling quality analysis of aircraft through variable flight conditions. Brief discussion of motion at high angles-of-attack, roll coupling, and other nonlinear flight regimes.
E. Frazzoli

16.338[J] Dynamic Systems and Control
______

Graduate (Spring)
(Same subject as6.241[J])
Prereq: 6.003, 18.06
Units: 4-0-8
______
Linear, discrete- and continuous-time, multi-input-output systems in control, related areas. Least squares and matrix perturbation problems. State-space models, modes, stability, controllability, observability, transfer function matrices, poles and zeros, and minimality. Internal stability of interconnected systems, feedback compensators, state feedback, optimal regulation, observers, and observer-based compensators. Measures of control performance, robustness issues using singular values of transfer functions. Introductory ideas on nonlinear systems. Recommended prerequisite: 6.302.
M. A. Dahleh, A. Megretski, E. Frazzoli

16.343 Spacecraft and Aircraft Sensors and Instrumentation
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Covers fundamental sensor and instrumentation principles in the context of systems designed for space or atmospheric flight. Systems discussed include basic measurement system for force, temperature, pressure; navigation systems (Global Positioning System, Inertial Reference Systems, radio navigation), air data systems, communication systems; spacecraft attitude determination by stellar, solar, and horizon sensing; remote sensing by incoherent and Doppler radar, radiometry, spectrometry, and interferometry. Also included is a review of basic electromagnetic theory and antenna design and discussion of design considerations for flight. Alternate years.
K. Cahoy, R. J. Hansman

16.346 Astrodynamics
______

Graduate (Spring)
Prereq: 18.03
Units: 3-0-9
______
Fundamentals of astrodynamics; the two-body orbital initial-value and boundary-value problems with applications to space vehicle navigation and guidance for lunar and planetary missions with applications to space vehicle navigation and guidance for lunar and planetary missions including both powered flight and midcourse maneuvers. Topics include celestial mechanics, Kepler's problem, Lambert's problem, orbit determination, multi-body methods, mission planning, and recursive algorithms for space navigation. Selected applications from the Apollo, Space Shuttle, and Mars exploration programs.
S. E. Widnall

16.35 Real-Time Systems and Software
______

Undergrad (Spring)
Prereq: 1.00, 6.0002, or 6.005
Units: 3-0-9
______
Concepts, principles, and methods for specifying and designing real-time computer systems. Topics include concurrency, real-time execution implementation, scheduling, testing, verification, real-time analysis, and software engineering concepts. Additional topics include operating system architecture, process management, and networking.
N. Roy

16.355[J] Concepts in the Engineering of Software
______

Graduate (Spring)
(Same subject asIDS.341[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Reading and discussion on issues in the engineering of software systems and software development project design. Includes the present state of software engineering, what has been tried in the past, what worked, what did not, and why. Topics may differ in each offering, but are chosen from the software process and life cycle; requirements and specifications; design principles; testing, formal analysis, and reviews; quality management and assessment; product and process metrics; COTS and reuse; evolution and maintenance; team organization and people management; and software engineering aspects of programming languages.
N. G. Leveson

16.36 Communication Systems and Networks
______

Undergrad (Spring)
(Subject meets with16.363)
Prereq: 16.002 or 6.003; 16.09 or 6.041B
Units: 3-0-9
______
Introduces the fundamentals of digital communications and networking. Topics include elements of information theory, sampling and quantization, coding, modulation, signal detection and system performance in the presence of noise. Study of data networking includes multiple access, reliable packet transmission, routing and protocols of the internet. Concepts discussed in the context of aerospace communication systems: aircraft communications, satellite communications, and deep space communications. Students taking graduate version complete additional assignments.
E. H. Modiano

16.363 Communication Systems and Networks
______

Graduate (Spring)
(Subject meets with16.36)
Prereq: 16.004 or 6.003; 16.09 or 6.041B
Units: 3-0-9
______
Introduces the fundamentals of digital communications and networking, focusing on the study of networks, including protocols, performance analysis, and queuing theory. Topics include elements of information theory, sampling and quantization, coding, modulation, signal detection and system performance in the presence of noise. Study of data networking includes multiple access, reliable packet transmission, routing and protocols of the internet. Concepts discussed in the context of aerospace communication systems: aircraft communications, satellite communications, and deep space communications. Students taking graduate version complete additional assignments.
E. H. Modiano

16.37[J] Data-Communication Networks
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as6.263[J])
Prereq: 6.041B or 18.204
Units: 3-0-9
______
Provides an introduction to data networks with an analytic perspective, using telephone networks, wireless networks, optical networks, the Internet and data centers as primary applications. Presents basic tools for modeling and performance analysis accompanied by elementary, meaningful simulations. Develops insights for large networks by means of simple approximations. Draws upon concepts from queueing theory and optimization.
E. Modiano, D. Shah

16.391[J] Statistics for Engineers and Scientists
______

Graduate (Fall)
(Same subject as6.434[J])
Prereq: Calculus II (GIR), 18.06, 6.431B, or permission of instructor
Units: 3-0-9
Lecture: MW1-2.30 (8-205)
______
Rigorous introduction to fundamentals of statistics motivated by engineering applications. Topics include exponential families, order statistics, sufficient statistics, estimation theory, hypothesis testing, measures of performance, notions of optimality, analysis of variance (ANOVA), simple linear regression, and selected topics.
M. Win, J. N. Tsitsiklis
No textbook information available

16.395 Principles of Wide Bandwidth Communication
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.011, 16.36, or permission of instructor
Units: 3-0-9
______
Introduction to the principles of wide bandwidth wireless communication, with a focus on ultra-wide bandwidth (UWB) systems. Topics include the basics of spread-spectrum systems, impulse radio, Rake reception, transmitted reference signaling, spectral analysis, coexistence issues, signal acquisition, channel measurement and modeling, regulatory issues, and ranging, localization and GPS. Consists of lectures and technical presentations by students.
M. Z. Win

Humans and Automation

16.400 Human Systems Engineering
______

Undergrad (Fall)
(Subject meets with16.453[J],HST.518[J])
Prereq: 6.041B, 16.09, or permission of instructor
Units: 3-0-9
Lecture: TR9.30-11 (37-212)
______
Provides a fundamental understanding of human factors that must be taken into account in the design and engineering of complex aviation, space, and medical systems. Focuses primarily on derivation of human engineering design criteria from sensory, motor, and cognitive sources. Includes principles of displays, controls and ergonomics, manual control, the nature of human error, basic experimental design, and human-computer interaction in supervisory control settings. Students taking graduate version complete a research project with a final written report and oral presentation.
L. A. Stirling
Textbooks (Fall 2016)

16.401 Topics in Communication and Software
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of department
Units arranged
TBA.
______
Provides credit for student work on undergraduate-level material in communications and/or software outside of regularly scheduled subjects. Intended for study abroad under either the department's Year Abroad Program or the Cambridge-MIT Exchange Program. Credit may be used to satisfy specific SB degree requirements. Requires prior approval. Consult department.
N. Roy
No textbook information available

16.405[J] Robotics: Science and Systems
______

Undergrad (Spring) Institute Lab
(Same subject as6.141[J])
Prereq: 1.00 or 6.0001; 2.003, 6.005, 6.006, 6.009, or 16.06; or permission of instructor
Units: 2-6-4
______
Presents concepts, principles, and algorithms for sensing and computation related to the physical world. Topics include motion planning, geometric reasoning, kinematics and dynamics, state estimation, tracking, map building, manipulation, human-robot interaction, fault diagnosis, and embedded system development. Students specify and design a small-scale yet complex robot capable of real-time interaction with the natural world. Students engage in extensive written and oral communication exercises. Enrollment limited.
S. Karaman, D. Rus

16.410 Principles of Autonomy and Decision Making
______

Undergrad (Fall)
(Subject meets with16.413)
Prereq: 1.00 or 6.0002
Units: 4-0-8
Lecture: MW9.30-11 (32-123) Recitation: F11 (33-419) or F3 (33-419) +final
______
Survey of reasoning, optimization and decision making methodologies for creating highly autonomous systems and decision support aids. Focus on principles, algorithms, and their application, taken from the disciplines of artificial intelligence and operations research. Reasoning paradigms include logic and deduction, heuristic and constraint-based search, model-based reasoning, planning and execution, and machine learning. Optimization paradigms include linear programming, integer programming, and dynamic programming. Decision-making paradigms include decision theoretic planning, and Markov decision processes. Students taking graduate version complete additional assignments.
B. C. Williams
No required or recommended textbooks

16.412[J] Cognitive Robotics
______

Graduate (Spring)
(Same subject as6.834[J])
Prereq: 6.041B, 6.042, or 16.09; 16.413 or 6.034
Units: 3-0-9
______
Algorithms and paradigms for creating a wide range of robotic systems that act intelligently and robustly, by reasoning extensively from models of themselves and their world. Examples range from autonomous Mars explorers and cooperative air vehicles, to everyday embedded devices. Topics include deduction and search in real-time; temporal, decision-theoretic and contingency planning; dynamic execution and re-planning; reasoning about hidden state and failures; reasoning under uncertainty, path planning, mapping and localization, and cooperative and distributed robotics. 8 Engineering Design Points.
B. C. Williams

16.413 Principles of Autonomy and Decision Making
______

Graduate (Fall)
(Subject meets with16.410)
Prereq: 1.00, 6.0002, 6.01, or permission of instructor
Units: 3-0-9
Lecture: MW9.30-11 (33-419) Recitation: F11 (33-419) +final
______
Graduate-level version of 16.410; see description under 16.410. Additional material on reasoning under uncertainty and machine learning, including hidden Markov models, graphical models and Bayesian networks, computational learning theory, reinforcement learning, decision tree learning and support vector machines. Assignments include the application of autonomy algorithms to practical aerospace systems, as well as more advanced programming assignments.
B. C. Williams
No required or recommended textbooks

16.420 Planning Under Uncertainty
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 16.413
Units: 3-0-9
______
Concepts, principles, and methods for planning with imperfect knowledge. Topics include state estimation, planning in information space, partially observable Markov decision processes, reinforcement learning and planning with uncertain models. Students will develop an understanding of how different planning algorithms and solutions techniques are useful in different problem domains. Previous coursework in artificial intelligence and state estimation strongly recommended.
Staff

16.422 Human Supervisory Control of Automated Systems
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-1-8
______
Principles of supervisory control and telerobotics. Different levels of automation are discussed, as well as the allocation of roles and authority between humans and machines. Human-vehicle interface design in highly automated systems. Decision aiding. Trade-offs between human control and human monitoring. Automated alerting systems and human intervention in automatic operation. Enhanced human interface technologies such as virtual presence. Performance, optimization, and social implications of the human-automation system. Examples from aerospace, ground, and undersea vehicles, robotics, and industrial systems.
J. A. Shah

16.423[J] Aerospace Biomedical and Life Support Engineering
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject asHST.515[J],IDS.940[J])
Prereq: 16.400, 16.06, or permission of instructor
Units: 3-1-8
______
Fundamentals of human performance, physiology, and life support impacting engineering design and aerospace systems. Topics include effects of gravity on the muscle, skeletal, cardiovascular, and neurovestibular systems; human/pilot modeling and human/machine design; flight experiment design; and life support engineering for extravehicular activity (EVA). Case studies of current research are presented. Assignments include a design project, quantitative homework sets, and quizzes emphasizing engineering and systems aspects.
D. J. Newman

16.430[J] Sensory-Neural Systems: Spatial Orientation from End Organs to Behavior and Adaptation
______

Graduate (Spring)
(Same subject asHST.514[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces sensory systems,and multi-sensory fusion using the vestibular and spatial orientation systems as a model. Topics range from end organ dynamics to neural responses, to sensory integration, to behavior, and adaptation, with particular application to balance, posture and locomotion under normal gravity and space conditions. Depending upon the background and interests of the students, advanced term project topics might include motion sickness, astronaut adaptation, artificial gravity, lunar surface locomotion, vestibulo-cardiovascular responses, vestibular neural prostheses, or other topics of interest. Background in neuroscience or systems engineering preferred.
D. Merfeld, F. Karmali

16.440[J] Research Seminar: Human, Remote and Autonomous Systems in Air, Sea, and Space
______

Graduate (Fall)
(Same subject asSTS.470[J])
Prereq: 16.400, 16.453, or permission of instructor
Units: 3-0-9
Lecture: W9-12 (4-146)
______
Examines relationships between human-occupied, remotely operated, and autonomous systems in the extreme environments of the deep ocean, air, and spaceflight. Uses a mix of historical, sociological, and engineering perspectives, examines different forms of human presence in each type of system and how they relate to each other in time and space, including: physical hand-on-the stick flying, supervisory control, remote operation, systems design, programming autonomous systems, management. Emphasis on networks of people interacting in networks of organizations through networks of machines.
D. A. Mindell
Textbooks (Fall 2016)

16.453[J] Human Systems Engineering
______

Graduate (Fall)
(Same subject asHST.518[J])
(Subject meets with16.400)
Prereq: 6.041B, 16.09, or permission of instructor
Units: 3-0-9
Lecture: TR9.30-11 (37-212)
______
Provides a fundamental understanding of human factors that must be taken into account in the design and engineering of complex aviation, space, and medical systems. Focuses primarily on derivation of human engineering design criteria from sensory, motor, and cognitive sources. Includes principles of displays, controls and ergonomics, manual control, the nature of human error, basic experimental design, and human-computer interaction in supervisory control settings. Students taking graduate version complete a research project with a final written report and oral presentation.
L. A. Stirling
Textbooks (Fall 2016)

16.456[J] Biomedical Signal and Image Processing
______

Graduate (Spring)
(Same subject as6.555[J],HST.582[J])
Prereq: 6.003, 2.004, 16.004, or 18.085
Units: 3-4-5
______
Fundamentals of digital signal processing with particular emphasis on problems in biomedical research and clinical medicine. Basic principles and algorithms for data acquisition, imaging, filtering, and feature extraction. Laboratory projects provide practical experience in processing physiological data, with examples from cardiology, speech processing, and medical imaging.
J. Greenberg, E. Adalsteinsson, W. Wells

16.459 Bioengineering Journal Article Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units: 1-0-1
URL: http://web.mit.edu/16.459/www/
Lecture: F2 (33-218)
______
Each term, the class selects a new set of professional journal articles on bioengineering topics of current research interest. Some papers are chosen because of particular content, others are selected because they illustrate important points of methodology. Each week, one student leads the discussion, evaluating the strengths, weaknesses, and importance of each paper. Subject may be repeated for credit a maximum of four terms. Letter grade given in the last term applies to all accumulated units of 16.459.
J. A. Hoffman, C. M. Oman, L. A. Stirling
No textbook information available

16.470 Statistical Methods in Experimental Design
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 6.041B, 16.09, or permission of instructor
Units: 3-0-9
______
Statistically based experimental design inclusive of forming hypotheses, planning and conducting experiments, analyzing data, and interpreting and communicating results. Topics include descriptive statistics, statistical inference, hypothesis testing, parametric and nonparametric statistical analyses, factorial ANOVA, randomized block designs, MANOVA, linear regression, repeated measures models, and application of statistical software packages.
C. L. Carr

16.475 Human-Computer Interface Design Colloquium
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: None
Units: 2-0-2
Subject Cancelled Subject Cancelled
______
Provides guidance on design and evaluation of human-computer interfaces for students with active research projects. Roundtable discussion on developing user requirements, human-centered design principles, and testing and evaluating methodologies. Students present their work and evaluate each other's projects. Readings complement specific focus areas. Team participation encouraged. Open to advanced undergraduates.
Staff

Propulsion and Energy Conversion

16.50 Aerospace Propulsion
______

Undergrad (Spring)
Prereq: 16.004 or 2.005
Units: 3-0-9
______
Presents aerospace propulsive devices as systems, with functional requirements and engineering and environmental limitations. Requirements and limitations that constrain design choices. Both air-breathing and rocket engines covered, at a level which enables rational integration of the propulsive system into an overall vehicle design. Mission analysis, fundamental performance relations, and exemplary design solutions presented.
S. Barrett

16.511 Aircraft Engines and Gas Turbines
______

Graduate (Fall)
Prereq: 16.50 or permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (33-422)
______
Performance and characteristics of aircraft jet engines and industrial gas turbines, as determined by thermodynamic and fluid mechanic behavior of engine components: inlets, compressors, combustors, turbines, and nozzles. Discusses various engine types, including advanced turbofan configurations, limitations imposed by material properties and stresses. Emphasizes future design trends including reduction of noise, pollutant formation, fuel consumption, and weight.
Z. S. Spakovszky
Textbooks (Fall 2016)

16.512 Rocket Propulsion
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 16.50 or permission of instructor
Units: 3-0-9
______
Chemical rocket propulsion systems for launch, orbital, and interplanetary flight. Modeling of solid, liquid-bipropellant, and hybrid rocket engines. Thermochemistry, prediction of specific impulse. Nozzle flows including real gas and kinetic effects. Structural constraints. Propellant feed systems, turbopumps. Combustion processes in solid, liquid, and hybrid rockets. Cooling; heat sink, ablative, and regenerative.
P. C. Lozano

16.522 Space Propulsion
______

Graduate (Spring)
Prereq: 16.50 or permission of instructor
Units: 3-3-6
______
Reviews rocket propulsion fundamentals. Discusses advanced concepts in rocket propulsion ranging from chemical engines to electrical engines. Topics include advanced mission analysis, physics and engineering of microthrusters, solid propellant rockets, electrothermal, electrostatic, and electromagnetic schemes for accelerating propellant. Some coverage is given of satellite power systems and their relation to propulsion systems. Laboratory work emphasizes design and characterization of electric propulsion engines.
P. C. Lozano

16.540 Internal Flows in Turbomachines
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 2.25 or permission of instructor
Units: 3-0-9
______
Internal fluid motions in turbomachines, propulsion systems, ducts and channels, and other fluid machinery. Useful basic ideas, fundamentals of rotational flows, loss sources and loss accounting in fluid devices, unsteady internal flow and flow instability, flow in rotating passages, swirling flow, generation of streamwise vorticity and three-dimensional flow, non-uniform flow in fluid components. Alternate years.
E. M. Greitzer

16.55 Ionized Gases
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 8.02 or permission of instructor
Units: 3-0-9
______
Properties and behavior of low-temperature plasmas for energy conversion, plasma propulsion, and gas lasers. Equilibrium of ionized gases: energy states, statistical mechanics, and relationship to thermodynamics. Kinetic theory: motion of charged particles, distribution function, collisions, characteristic lengths and times, cross sections, and transport properties. Gas surface interactions: thermionic emission, sheaths, and probe theory. Radiation in plasmas and diagnostics.
P. C. Lozano

Other Undergraduate Subjects

16.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually

16.EPE UPOP Engineering Practice Experience
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.EPE,2.EPE,3.EPE,6.EPE,10.EPE,16.EPE,22.EPE)
Prereq: 2.EPW or permission of instructor
Units: 0-0-1 [P/D/F]
TBA.
______
Provides sophomores with guided practice in finding opportunities and excelling in the world of practice. Building on the skills and relationships acquired in the Engineering Practice Workshop, students receive coaching to articulate goals, invoke the UPOP network of mentors and employers, identify and pursue opportunities and negotiate terms of their summer assignment. Students complete a 10-12 week internship, which includes filing three progress reports, conducting one informational interview, and possibly hosting a site visit by MIT staff. Returning to campus as juniors, UPOP students take part in reflective exercises that aid assimilation of learning objectives and reinforce the cognitive link between all aspects of the UPOP experience and disciplinary fields of study. Sequence begins in the spring of sophomore year and ends in the fall of junior year.
Staff
No textbook information available

16.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No textbook information available

16.S685 Special Subject in Aeronautics and Astronautics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Basic undergraduate topics not offered in regularly scheduled subjects. Subject to approval of faculty in charge. Prior approval required.
Consult M. A. Stuppard

16.S686 Special Subject in Aeronautics and Astronautics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Opportunity for study or lab work related to aeronautics and astronautics not covered in regularly scheduled subjects. Subject to approval of faculty in charge. Prior approval required.
Consult M. A. Stuppard
No textbook information available

16.S688 Special Subject in Aeronautics and Astronautics
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Opportunity for study or lab work related to aeronautics and astronautics but not covered in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard
No textbook information available


left arrow|16.00-16.599 plus UROP and EP|16.60-16.999 plus ThG|right arrow



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Course 16: Aeronautics and Astronautics
Fall 2016


16.621 Experimental Projects I
______

Undergrad (Fall, Spring)
Prereq: None.Coreq: 16.06 or 16.07
Units: 2-1-3
Lecture: TR1 (33-419)
______
First in a two-term sequence that addresses the conception and design of a student-defined or selected experimental research project carried out by two-person team under faculty advisement. Principles of research hypothesis formulation and assessment, experimental measurements and error analysis, and effective report writing and oral presentation, with instruction both in-class and on an individual and team basis. Selection and detailed planning of a research project, including in-depth design of experimental procedure that is then carried through to completion in 16.622.
B. L. Wardle, J. L. Craig, S. Hall, S. E. Widnall
No required or recommended textbooks

16.622 Experimental Projects II
______

Undergrad (Fall, Spring) Institute Lab
Prereq: 16.621
Units: 1-7-4
Lecture: TR1 (33-419) Lab: TR2-5 (31-GELB LAB)
______
Execution of research project experiments based on the plan developed in 16.621. Working with their faculty advisor and course staff, student teams construct their experiment, carry out measurements of the relevant phenomena, analyze the data, and then apply the results to assess the research hypothesis. Includes instruction on effective report writing and oral presentations culminating in a written final report and formal oral presentation.
B. L. Wardle, J. L. Craig, S. Hall, S. E. Widnall
No required or recommended textbooks

16.63[J] System Safety
______

Not offered academic year 2016-2017Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject asIDS.045[J])
Prereq: None
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Introduces the concepts of system safety and how to analyze and design safer systems. Topics include the causes of accidents in general, and recent major accidents in particular; hazard analysis, safety-driven design techniques; design of human-automation interaction; integrating safety into the system engineering process; and managing and operating safety-critical systems.
N. Leveson

16.64 Flight Measurement Laboratory
______

Undergrad (Spring)
Prereq: 16.002
Units: 2-2-2
______
Opportunity to see aeronautical theory applied in real-world environment of flight. Students assist in design and execution of simple engineering flight experiments in light aircraft. Typical investigations include determination of stability derivatives, verification of performance specifications, and measurement of navigation system characteristics. Restricted to students in Aeronautics and Astronautics.
R. J. Hansman

16.650 Engineering Leadership Lab
______

Undergrad (Fall, Spring) Can be repeated for credit
Engineering School-Wide Elective Subject.
(Offered under:6.911,16.650)
(Subject meets with6.913[J],16.667[J])
Prereq: None.Coreq: 6.912 or permission of instructor
Units: 0-2-1
Lab: F9-11 (32-124) or F1-3 (32-124) or F3-5 (32-124)
______
Exposes students to engineering frameworks, models, and cases in an interactive, experience-based environment, and hones leadership skills. Students participate in guided reflection on successes and discover opportunities for improvement in a controlled setting. Activities include design-implement activities, role-playing, simulations, case study analysis, and performance assessment by and of other students. Content throughout the term is frequently student-driven. First-year GEL Program students register for 6.911. Second-year GEL Program students register for 6.913. Preference to first-year students in the Bernard M. Gordon-MIT Engineering Leadership Program.
L. McGonagle, J. Feiler
No required or recommended textbooks

16.651 Engineering Leadership
______

Undergrad (Fall, Spring) Can be repeated for credit
Engineering School-Wide Elective Subject.
(Offered under:6.912,16.651)
Prereq: None.Coreq: 6.911 or permission of instructor
Units: 1-0-2
Lecture: M9-10.30 (5-233) or M11-12.30 (5-233) or T9-10.30 (5-233) or T11-12.30 (5-233)
______
Exposes students to the models and methods of engineering leadership within the contexts of conceiving, designing, implementing and operating products, processes and systems. Introduces models and theories, such as the Four Capabilities Framework and the Capabilities of Effective Engineering Leaders. Discusses the appropriate times and reasons to use particular models to deliver engineering success. Includes guest speakers and team projects that change from term to term. May be repeated for credit once with permission of instructor. Preference to first-year students in the Gordon Engineering Leadership Program.
J. Magarian, J. Schindall, L. McGonagle
No required or recommended textbooks

16.653 Management in Engineering
______

Undergrad (Fall)
Engineering School-Wide Elective Subject.
(Offered under:2.96,6.930,10.806,16.653)
Prereq: None
Units: 3-1-8
Lecture: MW11-12.30 (35-225) Lab: M4 (35-308) or T10 (1-273) or R4 (1-371) or F1 (1-132) or F2 (1-132)
______
Introduction and overview of engineering management. Financial principles, management of innovation, technical strategy and best management practices. Case study method of instruction emphasizes participation in class discussion. Focus is on the development of individual skills and management tools. Restricted to juniors and seniors.
H. S. Marcus, J.-H. Chun
No textbook information available

16.66 MATLAB Skills for Aeronautics and Astronautics
(16.99)
______

Undergrad (Fall); first half of term
Prereq: None
Units: 1-0-2 [P/D/F]
Ends Oct 26. Lecture: T12-2 (W31-301)
______
Introduction to basic MATLAB skills in programming, analysis, and plotting. Recommended for sophomores without previous MATLAB experience. Preference to Course 16 majors.
A. N. Marques
No required or recommended textbooks

16.662 Engineering Innovation and Design
(New)
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:2.723,6.902,16.662)
Prereq: None
Units: 3-0-3
Lecture: M EVE (7-9 PM) (32-155) Recitation: M EVE (9 PM) (32-155) or W EVE (7 PM) (2-105) or W EVE (8 PM) (2-105)
______
Project-based seminar in innovative design thinking develops students' ability to conceive, implement, and evaluate successful projects in any engineering discipline. Lectures focus on the iterative design process and techniques to enhance creative analysis. Students use this process to design and implement robust voice recognition applications using a simple web-based system. They also give presentations and receive feedback to sharpen their communication skills for high emotional and intellectual impact. Guest lectures illustrate multidisciplinary approaches to design thinking.
B. Kotelly
No textbook information available

16.667 Engineering Leadership Lab
______

Undergrad (Fall, Spring) Can be repeated for credit
Engineering School-Wide Elective Subject.
(Offered under:6.913,16.667)
(Subject meets with6.911[J],16.650[J])
Prereq: 6.911
Units: 0-2-4
Lab: F9-11 (32-124) or F1-3 (32-124) or F3-5 (32-124)
______
Exposes students to engineering frameworks, models, and cases in an interactive, experience-based environment, and hones leadership skills. Students participate in guided reflection on successes and discover opportunities for improvement in a controlled setting. Activities include design-implement activities, role-playing, simulations, case study analysis, and performance assessment by and of other students. Content throughout the term is frequently student-driven. First year GEL Program students register for 6.911. Second year GEL Program students register for 6.913. Preference to second-year students in the Bernard M. Gordon-MIT Engineering Leadership Program.
L. McGonagle, J. Feiler
No required or recommended textbooks

16.669 Project Engineering
______

Undergrad (IAP)
Engineering School-Wide Elective Subject.
(Offered under:6.914,16.669)
Prereq: 6.911 or permission of instructor
Units: 1-2-1 [P/D/F]
Credit cannot also be received for1.040
______
Students attend a four-day off-site workshop where an introduction to basic principles, methods, and tools for project management in a realistic context are covered. In teams, students create a plan for a project of their choice; past projects include Debris Removal in Haiti and Food Preparation Robot for Restaurants. Develops skills applicable to the management of complex development projects. Topics include cost-benefit analysis, resource and cost estimation, and project control and delivery. Case studies highlight projects in both hardware/construction and software. Preference to students in the Bernard M. Gordon-MIT Engineering Leadership Program.
O. de Weck

16.671[J] Leading Creative and Innovative Teams
(New)
______

Undergrad (Spring)
(Same subject as6.915[J])
Prereq: None
Units: 6-0-6
______
Empowers future leaders in technology by developing a foundation of personal and team leadership skills. Grounded in research and theory, focuses on practical leadership skills and how they can be assessed, learned, and applied to group situations in technical and engineering contexts. Focuses on how to foster original and creative thinking in groups, and how groups can successfully move creative ideas toward implementation and value creation. Balances traditional learning methods and more experiential ones, such as role play simulations and project-based learning. Enrollment limited to seating capacity of classroom. Admittance may be controlled by lottery.
D. Nino, J. Schindall

16.68 Modern Space Science and Engineering Seminar
______

Undergrad (Spring)
Prereq: None
Units: 2-0-4 [P/D/F]
______
Exposes students to the broad variety of scientific and technology experiments being carried out in space, and the complex engineering required to implement them. Fosters an appreciation for the interaction of science and engineering in the space enterprise. Specific topics vary from year to year.
J. A. Hoffman

16.680 Project in Aeronautics and Astronautics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Opportunity to work on projects related to aerospace engineering outside the department. Requires prior approval.
Consult M. A. Stuppard
No textbook information available

16.681 Topics in Aeronautics and Astronautics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Opportunity for study or laboratory project work not available elsewhere in the curriculum. Topics selected in consultation with the instructor.
Consult M. A. Stuppard
No textbook information available

16.682 Selected Topics in Aeronautics and Astronautics
______

Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Study by qualified students. Topics selected in consultation with the instructor. Prior approval required.
Consult M. A. Stuppard
No textbook information available

16.683 Seminar in Aeronautics and Astronautics
______

Not offered academic year 2017-2018Undergrad (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units: 2-0-0 [P/D/F]
TBA.
______
Speakers from campus and industry discuss current activities and advances in aeronautics and astronautics. Restricted to Course 16 students.
Consult M. A. Stuppard
Textbooks (Fall 2016)

16.687 Selected Topics in Aeronautics and Astronautics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Study by qualified students. Topics selected in consultation with the instructor. Prior approval required.
Consult M. A. Stuppard
No textbook information available

Flight Transportation

16.707[J] The History of Aviation
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject asSTS.467[J])
Prereq: Permission of Instructor
Units: 3-0-9
______
Reading course in the history of aviation, focusing on science and technology and cultural and political context. Themes include: the science of aeronautics, pilots and piloting, control systems and electronics, engineering epistemology, infrastructure, industry, government and politics, evolution of aeronautics research, culture and experience, automation and autonomy, role of MIT, literature and film. Case studies of specific systems and engineering projects. Emphasis is on book-length texts, close reading, historical methods of analyzing technological change. Study of social and political dimensions of engineering projects, examination of aviation institutions. Students prepare weekly response papers to readings, make extended presentations to class twice per semester, and submit a final research paper.
D. Mindell

16.71[J] The Airline Industry
______

Graduate (Fall)
(Same subject as1.232[J],15.054[J])
Prereq: None
Units: 3-0-9
Lecture: MW1-2.30 (35-225)
______
Overview of the global airline industry, focusing on recent industry performance, current issues and challenges for the future. Fundamentals of airline industry structure, airline economics, operations planning, safety, labor relations, airports and air traffic control, marketing, and competitive strategies, with an emphasis on the interrelationships among major industry stakeholders. Recent research findings of the MIT Global Airline Industry Program are showcased, including the impacts of congestion and delays, evolution of information technologies, changing human resource management practices, and competitive effects of new entrant airlines. Taught by faculty participants of the Global Airline Industry Program.
P. P. Belobaba, A. I. Barnett, C. Barnhart, R. J. Hansman, T. A. Kochan
Textbooks (Fall 2016)

16.715 Aerospace, Energy, and the Environment
______

Graduate (Fall)
Prereq: Chemistry (GIR); 1.060B, 2.006, 10.301,16.003, 16.004, or permission of instructor
Units: 3-0-9
Lecture: TR11-12.30 (33-319) +final
______
Addresses energy and environmental challenges facing aerospace in the 21st century. Topics include: aircraft performance and energy requirements, propulsion technologies, jet fuels and alternative fuels, lifecycle assessment of fuels, combustion, emissions, climate change due to aviation, aircraft contrails, air pollution impacts of aviation, impacts of supersonic aircraft, and aviation noise. Includes an in-depth introduction to the relevant atmospheric and combustion physics and chemistry with no prior knowledge assumed. Discussion and analysis of near-term technological, fuel-based, regulatory and operational mitigation options for aviation, and longer-term technical possibilities.
S. Barrett
No required or recommended textbooks

16.72 Air Traffic Control
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces the various aspects of present and future Air Traffic Control systems. Descriptions of the present system: systems-analysis approach to problems of capacity and safety; surveillance, including NAS and ARTS; navigation subsystem technology; aircraft guidance and control; communications; collision avoidance systems; sequencing and spacing in terminal areas; future directions and development; critical discussion of past proposals and of probable future problem areas. Requires term paper.
H. Balakrishnan

16.75[J] Airline Management
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as1.234[J])
Prereq: 16.71J
Units: 3-0-9
______
Overview of airline management decision processes, with a focus on economic issues and their relationship to operations planning models and decision support tools. Application of economic models of demand, pricing, costs, and supply to airline markets and networks. Examination of industry practice and emerging methods for fleet planning, route network design, scheduling, pricing and revenue management, with emphasis on the interactions between the components of airline management and profit objectives in competitive environments. Students participate in a competitive airline management simulation game as part of the subject requirements.
P. P. Belobaba

16.76[J] Logistical and Transportation Planning Methods
______

Graduate (Spring)
(Same subject as1.203[J],15.073[J])
Prereq: 6.041B
Units: 3-0-9
______
Quantitative techniques of operations research with emphasis on applications in transportation systems analysis (urban, air, ocean, highway, and pickup and delivery systems) and in the planning and design of logistically oriented urban service systems (e.g., fire and police departments, emergency medical services, and emergency repair services). Unified study of functions of random variables, geometrical probability, multi-server queuing theory, spatial location theory, network analysis and graph theory, and relevant methods of simulation. Computer exercises and discussions of implementation difficulties.
R. C. Larson, A. I. Barnett

16.763[J] Air Transportation Operations Research
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as1.233[J])
Prereq: 16.71, 6.431, 15.093, or permission of instructor
Units: 3-0-9
______
Presents a unified view of advanced quantitative analysis and optimization techniques applied to the air transportation sector. Considers the problem of operating and managing the aviation sector from the perspectives of the system operators (e.g., the FAA), the airlines, and the resultant impacts on the end-users (the passengers). Explores models and optimization approaches to system-level problems, airline schedule planning problems, and airline management challenges. Term paper required.
H. Balakrishnan, C. Barnhart, P. P. Belobaba

16.767 Introduction to Airline Transport Aircraft Systems and Automation
______

Graduate (IAP)
Prereq: Permission of instructor
Units: 3-2-1 [P/D/F]
______
Intensive one-week subject that uses the Boeing 767 aircraft as an example of a system of systems. Focuses on design drivers and compromises, system interactions, and human-machine interface. Morning lectures, followed by afternoon desktop simulator sessions. Critique and comparison with other transport aircraft designs. Includes one evening at Boston Logan International Airport aboard an aircraft. Enrollment limited.
C. M. Oman, B. Nield

16.781[J] Planning and Design of Airport Systems
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as1.231[J],IDS.670[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (1-379)
______
Focuses on current practice, developing trends, and advanced concepts in airport design and planning. Considers economic, environmental, and other trade-offs related to airport location, as well as the impacts of emphasizing "green" measures. Includes an analysis of the effect of airline operations on airports. Topics include demand prediction, determination of airfield capacity, and estimation of levels of congestion; terminal design; the role of airports in the aviation and transportation system; access problems; optimal configuration of air transport networks and implications for airport development; and economics, financing, and institutional aspects. Special attention to international practice and developments.
R. de Neufville, A. R. Odoni
Textbooks (Fall 2016)

Aerospace Systems

16.82 Flight Vehicle Engineering
______

Undergrad (Fall)
Prereq: Permission of instructor
Units: 3-3-6
Lecture: MW2-5 (33-419)
______
Design of an atmospheric flight vehicle to satisfy stated performance, stability, and control requirements. Emphasizes individual initiative, application of fundamental principles, and the compromises inherent in the engineering design process. Includes instruction and practice in written and oral communication, through team presentations and a written final report. Offered alternate Spring and Fall terms.
W. Hoburg, M. Drela, R. J. Hansman
No required or recommended textbooks

16.821 Flight Vehicle Development
______

Not offered academic year 2017-2018Undergrad (Spring) Institute Lab
Prereq: Permission of instructor
Units: 2-10-6
______
Focuses on implementation and operation of a flight system. Emphasizes system integration, implementation, and performance verification using methods of experimental inquiry, and addresses principles of laboratory safety. Students refine subsystem designs and fabricate working prototypes. Includes component integration into the full system with detailed analysis and operation of the complete vehicle in the laboratory and in the field, as well as experimental analysis of subsystem performance, comparison with physical models of performance and design goals, and formal review of the overall system design. Knowledge of the engineering design process is helpful. Provides instruction in written and oral communication.
R. J. Hansman, M. Drela

16.83[J] Space Systems Engineering
______

Undergrad (Spring)
(Same subject as 12.43[J])
Prereq: Permission of instructor
Units: 3-3-6
______
Design of a complete space system, including systems analysis, trajectory analysis, entry dynamics, propulsion and power systems, structural design, avionics, thermal and environmental control, human factors, support systems, and weight and cost estimates. Students participate in teams, each responsible for an integrated vehicle design, providing experience in project organization and interaction between disciplines. Includes several aspects of team communication including three formal presentations, informal progress reports, colleague assessments, and written reports. Course 16 students are expected to complete two professional or concentration subjects from the departmental program before taking this capstone. Offered alternate fall and spring terms.
J. A. Hoffman, A. Saenz-Otero

16.831[J] Space Systems Development
______

Not offered academic year 2016-2017Undergrad (Spring) Institute Lab
(Same subject as12.431[J])
Prereq: Permission of instructor
Units: 2-10-6
______
Students build a space system, focusing on refinement of sub-system designs and fabrication of full-scale prototypes. Sub-systems are integrated into a vehicle and tested. Sub-system performance is verified using methods of experimental inquiry, and is compared with physical models of performance and design goals. Communication skills are honed through written and oral reports. Formal reviews include the Implementation Plan Review and the Acceptance Review. Knowledge of the engineering design process is helpful.
J. A. Hoffman, A. Saenz-Otero

16.842 Fundamentals of Systems Engineering
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 2-0-4
Lecture: F9-11 (33-218)
______
General introduction to systems engineering using the classical V-model. Topics include stakeholder analysis, requirements definition, system architecture and concept generation, trade-space exploration and concept selection, human factors, design definition and optimization, system integration and interface management, system safety, verification and validation, and commissioning and operations. Discusses the trade-offs between performance, life-cycle cost and system operability. Readings based on systems engineering standards. Individual homework assignments apply concepts from class and contain both aeronautical and astronautical applications. Prepares students for the systems field exam in the Department of Aeronautics and Astronautics.
O. de Weck
No textbook information available

16.851 Satellite Engineering
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR12.30-2 (33-218)
______
Fundamentals of satellite engineering design, including distributed satellite. Studies orbital environment. Analyzes problems of station keeping, attitude control, communications, power generation, structural design, thermal balance, and subsystem integration. Considers trade-offs among weight, efficiency, cost, and reliability. Discusses choice of design parameters, such as size, weight, power levels, temperature limits, frequency, and bandwidth. Examples taken from current satellite systems.
K. Cahoy
Textbooks (Fall 2016)

16.852 Integrating The Lean Enterprise
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-0-9
______
Addresses some of the important issues involved with the planning, development, and implementation of lean enterprises. People, technology, process, and management dimensions of an effective lean manufacturing company are considered in a unified framework. Particular emphasis on the integration of these dimensions across the entire enterprise, including product development, production, and the extended supply chain. Analysis tools as well as future trends and directions are explored. A key component of this subject is a team project.
Staff

16.855[J] Systems Architecting Applied to Enterprises
______

Graduate (Spring)
(Same subject asIDS.336[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Focuses on principles and practices for architecting new and evolving sociotechnical enterprises. Includes reading and discussions of enterprise theory, contemporary challenges, and case studies of evolving enterprises. Covers frameworks and methods for ecosystem analysis, stakeholder analysis, architecture design and evaluation, and implementation strategies. Students work in small teams on projects to design a future architecture for a selected real-world enterprise.
D. Rhodes

16.861 Engineering Systems Analysis for Design
______

Graduate (Fall)
Engineering School-Wide Elective Subject.
(Offered under:1.146,16.861,IDS.332)
(Subject meets withIDS.333)
Prereq: 1.145 or permission of instructor
Units: 3-0-9
URL: http://msl1.mit.edu/mib/dsp/curricula.mit.edu/~dsplan/
Lecture: TR10.30-12 (1-390)
______
Covers theory and methods to identify, value, and implement flexibility in design, also known as "real options." Topics include definition of uncertainties, simulation of performance for scenarios, screening models to identify desirable flexibility, decision and lattice analysis, and multidimensional economic evaluation. Students demonstrate proficiency through an extended application to a systems design of their choice. Provides a complement to research or thesis projects. Meets with IDS.333 first half of term.
R. de Neufville
Textbooks (Fall 2016)

16.863[J] System Safety Concepts
______

Graduate (Fall)
(Same subject asIDS.340[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: F9-12 (33-422)
______
Covers important concepts and techniques in designing and operating safety-critical systems. Topics include the nature of risk, formal accident and human error models, causes of accidents, fundamental concepts of system safety engineering, system and software hazard analysis, designing for safety, fault tolerance, safety issues in the design of human-machine interaction, verification of safety, creating a safety culture, and management of safety-critical projects. Includes a class project involving the high-level system design and analysis of a safety-critical system.
N. G. Leveson
No textbook information available

16.885 Aircraft Systems Engineering
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: Permission of instructor
Units: 3-1-8
Lecture: MW2-4 (33-218)
______
Holistic view of the aircraft as a system, covering basic systems engineering, cost and weight estimation, basic aircraft performance, safety and reliability, life cycle topics, aircraft subsystems, risk analysis and management, and system realization. Small student teams retrospectively analyze an existing aircraft covering: key design drivers and decisions; aircraft attributes and subsystems; operational experience. Oral and written versions of the case study are delivered. Focuses on a systems engineering analysis of the Space Shuttle. Studies both design and operations of the shuttle, with frequent lectures by outside experts. Students choose specific shuttle systems for detailed analysis and develop new subsystem designs using state of the art technology.
R. J. Hansman, W. Hoburg
No textbook information available

16.886 Air Transportation Systems Architecting
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-2-7
______
Addresses the architecting of air transportation systems. Focuses on the conceptual phase of product definition including technical, economic, market, environmental, regulatory, legal, manufacturing, and societal factors. Centers on a realistic system case study and includes a number of lectures from industry and government. Past examples include the Very Large Transport Aircraft, a Supersonic Business Jet and a Next Generation Cargo System. Identifies the critical system level issues and analyzes them in depth via student team projects and individual assignments. Overall goal is to produce a business plan and a system specifications document that can be used to assess candidate systems.
R. J. Hansman

16.888[J] Multidisciplinary System Design Optimization
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject asIDS.338[J])
Prereq: 18.085 or permission of instructor
Units: 3-1-8
______
Engineering systems modeling for design and optimization. Selection of design variables, objective functions and constraints. Overview of principles, methods and tools in multidisciplinary design optimization (MDO). Subsystem identification, development and interface design. Review of linear and non-linear constrained optimization formulations. Scalar versus vector optimization problems from systems engineering and architecting of complex systems. Heuristic search methods: Tabu search, simulated annealing, genetic algorithms. Sensitivity, tradeoff analysis and isoperformance. Multiobjective optimization and pareto optimality. Surrogate and multifidelity optimization strategies. System design for value. Specific applications from aerospace, mechanical, civil engineering and system architecture.
O. de Weck, K. E. Willcox

16.89[J] Space Systems Engineering
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject asIDS.339[J])
Prereq: 16.851 or permission of instructor
Units: 4-2-6
______
Focus on developing space system architectures. Applies subsystem knowledge gained in 16.851 to examine interactions between subsystems in the context of a space system design. Principles and processes of systems engineering including developing space architectures, developing and writing requirements, and concepts of risk are explored and applied to the project. Subject develops, documents, and presents a conceptual design of a space system including a preliminary spacecraft design.
O. de Weck

16.895[J] Engineering Apollo: The Moon Project as a Complex System
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject asSTS.471[J])
Prereq: Permission of instructor
Units: 4-0-8
______
Detailed technical and historical exploration of the Apollo project to fly humans to the moon and return them safely to Earth as an example of a complex engineering system. Emphasizes how the systems worked, the technical and social processes that produced them, mission operations, and historical significance. Guest lectures by MIT-affiliated engineers who contributed to and participated in the Apollo missions. Students work in teams on a final project analyzing an aspect of the historical project to articulate and synthesize ideas in engineering systems.
D. Mindell

Computation

16.90 Computational Methods in Aerospace Engineering
______

Undergrad (Spring)
Prereq: 16.001, 16.002, 16.003, 16.004, or permission of instructor;Coreq: 16.09 or 6.041B
Units: 3-0-9
______
Introduction to computational techniques arising in aerospace engineering. Techniques include numerical integration of systems of ordinary differential equations; numerical discretization of partial differential equations; and probabilistic methods for quantifying the impact of variability. Specific emphasis will be given to finite volume methods in fluid mechanics, and energy and finite element methods in structural mechanics.
R. Radovitzky, D. L. Darmofal

16.910[J] Introduction to Numerical Simulation
______

Graduate (Fall)
(Same subject as2.096[J],6.336[J])
Prereq: 18.03 or 18.06
Units: 3-3-6
Lecture: MW1-2.30 (32-141)
______
Introduction to computational techniques for the simulation of a large variety of engineering and physical systems. Applications are drawn from aerospace, mechanical, electrical, chemical engineering, biology, and materials science. Topics include mathematical formulations (techniques for automatic assembly of mathematical problems from physics' principles); sparse, direct and iterative solution techniques for linear systems; Newton and Homotopy methods for nonlinear problems; discretization methods for ordinary, time-periodic and partial differential equations; accelerated methods for integral equations; techniques for automatic generation of compact dynamical system models and model order reduction.
L. Daniel, J. K. White
No required or recommended textbooks

16.920[J] Numerical Methods for Partial Differential Equations
______

Graduate (Fall)
(Same subject as2.097[J],6.339[J])
Prereq: 18.03 or 18.06
Units: 3-0-9
Lecture: MW9.30-11 (4-163)
______
Covers the fundamentals of modern numerical techniques for a wide range of linear and nonlinear elliptic, parabolic, and hyperbolic partial differential and integral equations. Topics include mathematical formulations; finite difference, finite volume, finite element, and boundary element discretization methods; and direct and iterative solution techniques. The methodologies described form the foundation for computational approaches to engineering systems involving heat transfer, solid mechanics, fluid dynamics, and electromagnetics. Computer assignments requiring programming.
Q. Wang, J. K. White
No textbook information available

16.930 Advanced Topics in Numerical Methods for Partial Differential Equations
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 16.920
Units: 3-0-9
______
Covers advanced topics in numerical methods for the discretization, solution, and control of problems governed by partial differential equations. Topics include the application of the finite element method to systems of equations with emphasis on equations governing compressible, viscous flows; grid generation; optimal control of PDE-constrained systems; a posteriori error estimation and adaptivity; reduced basis approximations and reduced-order modeling. Computer assignments require programming.
Staff

16.940 Numerical Methods for Stochastic Modeling and Inference
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 16.920, 6.431; or permission of instructor
Units: 3-0-9
______
Advanced introduction to numerical methods for treating uncertainty in computational simulation. Draws examples from a range of engineering and science applications, emphasizing systems governed by ordinary and partial differential equations. Uncertainty propagation and assessment: Monte Carlo methods, variance reduction, sensitivity analysis, adjoint methods, polynomial chaos and Karhunen-Loève expansions, and stochastic Galerkin and collocation methods. Interaction of models with observational data, from the perspective of statistical inference: Bayesian parameter estimation, statistical regularization, Markov chain Monte Carlo, sequential data assimilation and filtering, and model selection.
Y. M. Marzouk

Other Graduate Subjects

16.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of department
Units arranged
TBA.
______
Program of research leading to an SM, EAA, PhD, or ScD thesis; to be arranged by the student with an appropriate MIT faculty member, who becomes thesis supervisor. Restricted to students who have been admitted into the department.
Y. M. Marzouk
Textbooks arranged individually

16.980 Advanced Project
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
No textbook information available

16.981 Advanced Project
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Study, original investigation, or lab project work by qualified students. Topics selected in consultation with instructor. Prior approval required.
Consult M. A. Stuppard
No textbook information available

16.984 Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: None
Units: 2-0-0 [P/D/F]
______
Discussion of current interest topics by staff and guest speakers. Prior approval required. Restricted to Course 16 students.
Consult M. A. Stuppard

16.985[J] Global Operations Leadership Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
(Same subject as2.890[J],10.792[J],15.792[J])
Prereq: None
Units arranged [P/D/F]
Lecture: M EVE (4-6 PM) (E62-262)
______
Integrative forum in which worldwide leaders in business, finance, government, sports, and education share their experiences and insights with students aspiring to run global operations. Students play a large role in managing the seminar. Preference to LGO students.
T. Roemer
No textbook information available

16.990[J] Leading Creative Teams
(New)
______

Graduate (Fall, Spring)
(Same subject as6.928[J])
Prereq: None
Units: 3-1-5
Lecture: F9.30-12.30 (5-233) Lab: W3 (56-154) or F12.30 (5-233)
______
Prepares students to lead teams charged with developing creative solutions to challenging problems. Grounded in research but practical in focus, covers the development of basic leadership capabilities, such as motivating and influencing others, delegating, managing conflict, and communicating effectively; how to create, launch, develop, and adjourn teams; and how to foster creativity in small groups.
D. Nino, J. Schindall
No textbook information available

16.999 Teaching in Aeronautics and Astronautics
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
For qualified students interested in gaining teaching experience. Classroom, tutorial, or laboratory teaching under the supervision of a faculty member. Enrollment limited by availability of suitable teaching assignments. Consult department.
Y. M. Marzouk
No textbook information available

16.S198 Advanced Special Subject in Mechanics and Physics of Fluids
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled fluids subjects. Prior approval required.
Consult M. A. Stuppard

16.S199 Advanced Special Subject in Mechanics and Physics of Fluids
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled fluids subjects. Prior approval required.
Consult M. A. Stuppard

16.S298 Advanced Special Subject in Materials and Structures
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled materials and structures subjects. Prior approval required.
Consult M. A. Stuppard

16.S299 Advanced Special Subject in Materials and Structures
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled materials and structures subjects. Prior approval required.
Consult M. A. Stuppard

16.S398 Advanced Special Subject in Information and Control
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S399 Advanced Special Subject in Information and Control
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S498 Advanced Special Subject in Humans and Automation
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S499 Advanced Special Subject in Humans and Automation
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S598 Advanced Special Subject in Propulsion and Energy Conversion
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S599 Advanced Special Subject in Propulsion and Energy Conversion
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S798 Advanced Special Subject in Flight Transportation
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S799 Advanced Special Subject in Flight Transportation
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S898 Advanced Special Subject in Aerospace Systems
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard
No textbook information available

16.S899 Advanced Special Subject in Aerospace Systems
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard
No textbook information available

16.S948 Advanced Special Subject in Computation
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S949 Advanced Special Subject in Computation
______

Graduate (Fall, Spring) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of instructor
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard

16.S982 Advanced Special Subject
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Not offered regularly; consult department
Prereq: Permission of department
Units arranged
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
M. A. Stuppard

16.S983 Advanced Special Subject
______

Graduate (Fall, IAP, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Organized lecture or laboratory subject consisting of material not available in regularly scheduled subjects. Prior approval required.
Consult M. A. Stuppard
No textbook information available


left arrow|16.00-16.599 plus UROP and EP|16.60-16.999 plus ThG|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 18: Mathematics
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Course 18: Mathematics
Fall 2016


General Mathematics

18.01 Calculus
______

Undergrad (Fall, Spring) Calculus I
Prereq: None
Units: 5-0-7
Credit cannot also be received for18.014,18.01A,CC.181A,ES.1801,ES.181A
URL: http://www-math.mit.edu/18.01/
Lecture: TR1,F2 (54-100) Recitation: MW10 (2-139) or MW11 (2-139) or MW12 (36-112) or MW1 (36-112, 36-153) or MW2 (36-153) +final
______
Differentiation and integration of functions of one variable, with applications. Informal treatment of limits and continuity. Differentiation: definition, rules, application to graphing, rates, approximations, and extremum problems. Indefinite integration; separable first-order differential equations. Definite integral; fundamental theorem of calculus. Applications of integration to geometry and science. Elementary functions. Techniques of integration. Polar coordinates. L'Hopital's rule. Improper integrals. Infinite series: geometric, p-harmonic, simple comparison tests, power series for some elementary functions.
Fall:J. Speck
Spring: Information: J. W. Bush
Textbooks (Fall 2016)

18.01A Calculus
______

Undergrad (Fall) Calculus I; first half of term
Prereq: Knowledge of differentiation and elementary integration
Units: 5-0-7
Credit cannot also be received for18.01,18.014,CC.181A,ES.1801,ES.181A
Ends Oct 21. Lecture: TR1,F2 (E25-111) Recitation: MW10 (2-132) or MW11 (2-132) or MW12 (2-136) or MW1 (2-136, 4-149) or MW2 (4-149)
______
Six-week review of one-variable calculus, emphasizing material not on the high-school AB syllabus: integration techniques and applications, improper integrals, infinite series, applications to other topics, such as probability and statistics, as time permits. Prerequisites: one year of high-school calculus or the equivalent, with a score of 4 or 5 on the AB Calculus test (or the AB portion of the BC test, or an equivalent score on a standard international exam), or equivalent college transfer credit, or a passing grade on the first half of the 18.01 advanced standing exam.
G. Staffilani
Textbooks (Fall 2016)

18.014 Calculus with Theory
______

Undergrad (Fall) Calculus I
Prereq: None
Units: 5-0-7
Credit cannot also be received for18.01,18.01A,CC.181A,ES.1801,ES.181A
URL: http://math.mit.edu/classes/18.014
Lecture: TR1,F2 (2-131) Recitation: MW2 (2-131) +final
______
Covers the same material as 18.01, but at a deeper and more rigorous level. Emphasizes careful reasoning and understanding of proofs. Assumes knowledge of elementary calculus. Topics: axioms for the real numbers; the Riemann integral; limits, theorems on continuous functions; derivatives of functions of one variable; the fundamental theorems of calculus; Taylor's theorem; infinite series, power series, rigorous treatment of the elementary functions.
M. McBreen
Textbooks (Fall 2016)

18.02 Calculus
______

Undergrad (Fall, Spring) Calculus II
Prereq: Calculus I (GIR)
Units: 5-0-7
Credit cannot also be received for18.022,18.024,18.02A,CC.1802,CC.182A,ES.1802,ES.182A
URL: http://math.mit.edu/classes/18.02
Lecture: TR1,F2 (26-100) Recitation: MW9 (2-142) or MW10 (2-142, 36-156, 2-136) or MW11 (36-156, 2-136, 36-144, 36-153) or MW12 (2-132, 36-153, 2-143, 2-142) or MW1 (2-143, 2-142, 2-139, 56-180, 2-146) or MW2 (2-139, 56-180, 2-146, 2-136, 2-147) or MW3 (2-136, 2-147) +final
______
Calculus of several variables. Vector algebra in 3-space, determinants, matrices. Vector-valued functions of one variable, space motion. Scalar functions of several variables: partial differentiation, gradient, optimization techniques. Double integrals and line integrals in the plane; exact differentials and conservative fields; Green's theorem and applications, triple integrals, line and surface integrals in space, Divergence theorem, Stokes' theorem; applications.
Fall:W. Minicozzi
Spring:L. Guth
Textbooks (Fall 2016)

18.02A Calculus
______

Undergrad (Fall, IAP, Spring) Calculus II
Prereq: Calculus I (GIR)
Units: 5-0-7
Credit cannot also be received for18.02,18.022,18.024,CC.1802,CC.182A,ES.1802,ES.182A
URL: http://math.mit.edu/classes/18.02A
Begins Oct 24. Lecture: TR1,F2 (E25-111) Recitation: MW10 (2-132) or MW11 (2-132) or MW12 (2-136) or MW1 (2-136, 4-149) or MW2 (4-149) +final
______
First half is taught during the last six weeks of the Fall term; covers material in the first half of 18.02 (through double integrals). Second half of 18.02A can be taken either during IAP (daily lectures) or during the second half of the Spring term; it covers the remaining material in 18.02.
N. Stoop
Textbooks (Fall 2016)

18.022 Calculus
______

Undergrad (Fall) Calculus II
Prereq: Calculus I (GIR)
Units: 5-0-7
Credit cannot also be received for18.02,18.024,18.02A,CC.1802,CC.182A,ES.1802,ES.182A
Lecture: TR1,F2 (4-270) Recitation: MW11 (2-135) or MW12 (2-131) or MW1 (2-135) or MW2 (2-143) +final
______
Calculus of several variables. Topics as in 18.02 but with more focus on mathematical concepts. Vector algebra, dot product, matrices, determinant. Functions of several variables, continuity, differentiability, derivative. Parametrized curves, arc length, curvature, torsion. Vector fields, gradient, curl, divergence. Multiple integrals, change of variables, line integrals, surface integrals. Stokes' theorem in one, two, and three dimensions.
P. I. Etingof
Textbooks (Fall 2016)

18.024 Calculus with Theory
______

Undergrad (Spring) Calculus II
Prereq: Calculus I (GIR), permission of Instructor
Units: 5-0-7
Credit cannot also be received for18.02,18.022,18.02A,CC.1802,CC.182A,ES.1802,ES.182A
______
Continues 18.014. Parallel to 18.02, but at a deeper level, emphasizing careful reasoning and understanding of proofs. Considerable emphasis on linear algebra and vector integral calculus.
M. McBreen

18.03 Differential Equations
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: None.Coreq: Calculus II (GIR)
Units: 5-0-7
Credit cannot also be received for18.034,CC.1803,ES.1803
URL: http://math.mit.edu/classes/18.03
Lecture: MWF1 (54-100) Recitation: TR10 (2-147) or TR11 (2-147, 2-139) or TR12 (2-139, 2-147) or TR1 (2-147, 2-132, 2-142) or TR2 (2-147) or TR3 (2-147) +final
______
Study of differential equations, including modeling physical systems. Solution of first-order ODEs by analytical, graphical, and numerical methods. Linear ODEs with constant coefficients. Complex numbers and exponentials. Inhomogeneous equations: polynomial, sinusoidal, and exponential inputs. Oscillations, damping, resonance. Fourier series. Matrices, eigenvalues, eigenvectors, diagonalization. First order linear systems: normal modes, matrix exponentials, variation of parameters. Heat equation, wave equation. Nonlinear autonomous systems: critical point analysis, phase plane diagrams.
Fall:J. Dunkel
Spring:L. Demanet
No required or recommended textbooks

18.031 System Functions and the Laplace Transform
______

Undergrad (IAP)
Prereq: 18.03
Units: 1-0-2 [P/D/F]
______
Studies basic continuous control theory as well as representation of functions in the complex frequency domain. Covers generalized functions, unit impulse response, and convolution; and Laplace transform, system (or transfer) function, and the pole diagram. Includes examples from mechanical and electrical engineering.
Information: J. W. Bush

18.034 Differential Equations
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: None.Coreq: Calculus II (GIR)
Units: 5-0-7
Credit cannot also be received for18.03,CC.1803,ES.1803
URL: http://math.mit.edu/classes/18.034
______
Covers much of the same material as 18.03 with more emphasis on theory. The point of view is rigorous and results are proven. Local existence and uniqueness of solutions.
T. Colding

18.04 Complex Variables with Applications
______

Undergrad (Spring)
Prereq: Calculus II (GIR); 18.03 or 18.034
Units: 4-0-8
Credit cannot also be received for18.075,18.0751
URL: http://math.mit.edu/18.04/
______
Complex algebra and functions; analyticity; contour integration, Cauchy's theorem; singularities, Taylor and Laurent series; residues, evaluation of integrals; multivalued functions, potential theory in two dimensions; Fourier analysis, Laplace transforms, and partial differential equations.
J. Orloff

18.05 Introduction to Probability and Statistics
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR)
Units: 4-0-8
URL: http://math.mit.edu/classes/18.05
______
Elementary introduction with applications. Basic probability models. Combinatorics. Random variables. Discrete and continuous probability distributions. Statistical estimation and testing. Confidence intervals. Introduction to linear regression.
D. A. Vogan

18.06 Linear Algebra
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR)
Units: 4-0-8
Credit cannot also be received for18.700
URL: http://web.mit.edu/18.06/www/
Lecture: MWF11 (54-100) Recitation: T9 (38-166) or T10 (38-166, 2-146) or T11 (38-166) or T12 (38-166) or T1 (38-166) or T2 (38-166, 2-142) or T3 (2-142) +final
______
Basic subject on matrix theory and linear algebra, emphasizing topics useful in other disciplines, including systems of equations, vector spaces, determinants, eigenvalues, singular value decomposition, and positive definite matrices. Applications to least-squares approximations, stability of differential equations, networks, Fourier transforms, and Markov processes. Uses MATLAB. Compared with 18.700, more emphasis on matrix algorithms and many applications.
Fall:C. Barwick
Spring:S. G. Johnson
Textbooks (Fall 2016)

18.062[J] Mathematics for Computer Science
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
(Same subject as6.042[J])
Prereq: Calculus I (GIR)
Units: 5-0-7
URL: http://theory.csail.mit.edu/classes/6.042
Lecture: TR2.30-4 (26-100) Recitation: WF9 (38-166) or WF10 (38-166) or WF11 (38-166) or WF12 (38-166) or WF1 (38-166) or WF2 (38-166) or WF3 (38-166) or WF4 (38-166) or WF10 (13-3101) or WF11 (13-3101) or WF12 (13-3101) or WF1 (13-3101) or WF2 (13-3101) or WF3 (13-3101) or WF4 (13-3101) or WF10 (26-168) or WF11 (26-168) or WF12 (26-168) or WF1 (26-168) or WF2 (26-168) or WF3 (26-168) or WF4 (26-168) or WF11 (24-112) or WF12 (24-112) or WF1 (24-112) or WF9 (26-168) +final
______
Elementary discrete mathematics for computer science and engineering. Emphasis on mathematical definitions and proofs as well as on applicable methods. Topics include formal logic notation, proof methods; induction, well-ordering; sets, relations; elementary graph theory; asymptotic notation and growth of functions; permutations and combinations, counting principles; discrete probability. Further selected topics include recursive definition and structural induction, state machines and invariants, integer congruences, recurrences, generating functions.
F. T. Leighton, A. R. Meyer, A. Moitra
No required or recommended textbooks

18.065 Matrix Methods in Data Analysis, Signal Processing, and Machine Learning
(New)
______

Undergrad (Spring)
(Subject meets with18.0651)
Prereq: 18.06
Units: 3-0-9
______
Reviews linear algebra with applications to life sciences, finance, and big data. Covers singular value decomposition, weighted least squares, signal and image processing, principal component analysis, covariance and correlation matrices, directed and undirected graphs, matrix factorizations, neural nets, machine learning, and hidden Markov models. Students taking graduate version complete additional assignments.
G. Strang

18.075 Methods for Scientists and Engineers
______

Undergrad (Spring)
(Subject meets with18.0751)
Prereq: Calculus II (GIR); 18.03
Units: 3-0-9
Credit cannot also be received for18.04
URL: http://math.mit.edu/classes/18.075
______
Covers functions of a complex variable; calculus of residues. Includes ordinary differential equations; Bessel and Legendre functions; Sturm-Liouville theory; partial differential equations; heat equation; and wave equations.
H. Cheng

18.0751 Methods for Scientists and Engineers
______

Graduate (Spring)
(Subject meets with18.075)
Prereq: Calculus II (GIR); 18.03
Units: 3-0-9
Credit cannot also be received for18.04
______
Covers functions of a complex variable; calculus of residues. Includes ordinary differential equations; Bessel and Legendre functions; Sturm-Liouville theory; partial differential equations; heat equation; and wave equations. Students in Courses 6, 8, 12, 18, and 22 must register for undergraduate version, 18.075.
H. Cheng

18.085 Computational Science and Engineering I
______

Undergrad (Fall, Spring, Summer)
(Subject meets with18.0851)
Prereq: Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9
URL: http://math.mit.edu/classes/18.085
Lecture: TR11-12.30 (2-190)
______
Review of linear algebra, applications to networks, structures, and estimation, finite difference and finite element solution of differential equations, Laplace's equation and potential flow, boundary-value problems, Fourier series, discrete Fourier transform, convolution. Frequent use of MATLAB in a wide range of scientific and engineering applications.
Fall:G. Strang
Spring:P. Saenz
Textbooks (Summer 2016); Textbooks (Fall 2016)
______
Summer 2016 Description for Computational Science and Engineering I
(Subject meets with 18.0851)
Prereq:Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9


Review of linear algebra, applications to networks, structures, and estimation, finite difference and finite element solution of differential equations, Laplace's equation and potential flow, boundary-value problems, Fourier series, discrete Fourier transform, convolution. Frequent use of MATLAB in a wide range of scientific and engineering applications.

A. Forrow, J. Slomka
Section: MWF 9:30 AM-11:00 AM Room 2-131 From 06-JUN-16 Thru 12-AUG-16
Textbooks (Spring 2016); Textbooks (Summer 2016)

18.0851 Computational Science and Engineering I
______

Graduate (Fall, Spring, Summer)
(Subject meets with18.085)
Prereq: Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9
Lecture: TR11-12.30 (2-190)
______
Review of linear algebra, applications to networks, structures, and estimation, finite difference and finite element solution of differential equations, Laplace's equation and potential flow, boundary-value problems, Fourier series, discrete Fourier transform, convolution. Frequent use of MATLAB in a wide range of scientific and engineering applications. Students in Course 18 must register for the undergraduate version, 18.085.
Fall:G. Strang
Spring:P. Saenz
Textbooks (Summer 2016); Textbooks (Fall 2016)
______
Summer 2016 Description for Computational Science and Engineering I
(Subject meets with 18.085)
Prereq:Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9


Review of linear algebra, applications to networks, structures, and estimation, finite difference and finite element solution of differential equations, Laplace's equation and potential flow, boundary-value problems, Fourier series, discrete Fourier transform, convolution. Frequent use of MATLAB in a wide range of scientific and engineering applications. Students in Course 18 must register for the undergraduate version, 18.085.

A. Forrow, J. Slomka
Section: MWF 9:30 AM-11:00 AM Room 2-131 From 06-JUN-16 Thru 12-AUG-16
Textbooks (Spring 2016); Textbooks (Summer 2016)

18.086 Computational Science and Engineering II
______

Undergrad (Spring)
(Subject meets with18.0861)
Prereq: Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9
URL: http://math.mit.edu/18086/
______
Initial value problems: finite difference methods, accuracy and stability, heat equation, wave equations, conservation laws and shocks, level sets, Navier-Stokes. Solving large systems: elimination with reordering, iterative methods, preconditioning, multigrid, Krylov subspaces, conjugate gradients. Optimization and minimum principles: weighted least squares, constraints, inverse problems, calculus of variations, saddle point problems, linear programming, duality, adjoint methods.
H. Reid

18.0861 Computational Science and Engineering II
______

Graduate (Spring)
(Subject meets with18.086)
Prereq: Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9
______
Initial value problems: finite difference methods, accuracy and stability, heat equation, wave equations, conservation laws and shocks, level sets, Navier-Stokes. Solving large systems: elimination with reordering, iterative methods, preconditioning, multigrid, Krylov subspaces, conjugate gradients. Optimization and minimum principles: weighted least squares, constraints, inverse problems, calculus of variations, saddle point problems, linear programming, duality, adjoint methods. Students in Course 18 must register for the undergraduate version, 18.086.
H. Reid

18.089 Review of Mathematics
______

Graduate (Summer)
Prereq: Permission of instructor
Units: 5-0-7
______
One-week review of one-variable calculus (18.01), followed by concentrated study covering multivariable calculus (18.02), two hours per day for five weeks. Primarily for graduate students in Course 2N. Degree credit allowed only in special circumstances.
Information: J. W. Bush
Textbooks (Summer 2016)
______
Summer 2016 Description for Review of Mathematics
Prereq:Permission of instructor
Units: 5-0-7


One-week review of one-variable calculus (18.01), followed by concentrated study covering multivariable calculus (18.02), two hours per day for five weeks. Primarily for graduate students in Course 2N. Degree credit allowed only in special circumstances.

B. Yang, C. Sauer-Ayala
Section: Schedule TBD
Textbooks (Summer 2016)

18.094[J] Teaching College-Level Science and Engineering
______

Graduate (Fall)
(Same subject as1.95[J],5.95[J],7.59[J],8.395[J])
(Subject meets with2.978)
Prereq: None
Units: 2-0-2 [P/D/F]
URL: https://wikis.mit.edu/confluence/pages/viewpage.action?pageId=110876412
Lecture: R9-11 (4-149)
______
Participatory seminar focuses on the knowledge and skills necessary for teaching science and engineering in higher education. Topics include theories of adult learning; course development; promoting active learning, problemsolving, and critical thinking in students; communicating with a diverse student body; using educational technology to further learning; lecturing; creating effective tests and assignments; and assessment and evaluation. Students research and present a relevant topic of particular interest. Appropriate for both novices and those with teaching experience.
J. Rankin
No textbook information available

18.095 Mathematics Lecture Series
______

Undergrad (IAP) Can be repeated for credit
Prereq: Calculus I (GIR)
Units: 2-0-4 [P/D/F]
URL: http://math.mit.edu/classes/18.095/
______
Ten lectures by mathematics faculty members on interesting topics from both classical and modern mathematics. All lectures accessible to students with calculus background and an interest in mathematics. At each lecture, reading and exercises are assigned. Students prepare these for discussion in a weekly problem session.
Information: J. W. Bush

18.098 Internship in Mathematics
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Provides academic credit for students pursuing internships to gain practical experience in the applications of mathematical concepts and methods.
Information: J. W. Bush
No required or recommended textbooks

18.099 Independent Study
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Studies (during IAP) or special individual reading (during regular terms). Arranged in consultation with individual faculty members and subject to departmental approval.
Information: J. W. Bush
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

Analysis

18.1001 Real Analysis
______

Graduate (Fall, Spring)
(Subject meets with18.100A)
Prereq: Calculus II (GIR); or 18.014 andCoreq: Calculus II (GIR)
Units: 3-0-9
Credit cannot also be received for18.100B,18.100P,18.100Q
Lecture: MWF1 (4-163) +final
______
Textbooks (Fall 2016)

18.1002 Real Analysis
______

Graduate (Fall, Spring)
(Subject meets with18.100B)
Prereq: Calculus II (GIR); or 18.014 andCoreq: Calculus II (GIR)
Units: 3-0-9
Credit cannot also be received for18.100A,18.100Q
Lecture: MWF2 (2-190) +final
______
Textbooks (Fall 2016)

18.100A Real Analysis
______

Undergrad (Fall, Spring)
(Subject meets with18.1001)
Prereq: Calculus II (GIR); or 18.014 andCoreq: Calculus II (GIR)
Units: 3-0-9
Credit cannot also be received for18.100B,18.100P,18.100Q
Lecture: MWF1 (4-163) +final
______
Textbooks (Fall 2016)

18.100B Real Analysis
______

Undergrad (Fall, Spring)
(Subject meets with18.1002)
Prereq: Calculus II (GIR); or 18.014 andCoreq: Calculus II (GIR)
Units: 3-0-9
Credit cannot also be received for18.100A,18.100Q
URL: http://www.mit.edu/~jzahl/teaching/18100B.html
Lecture: MWF2 (2-190) +final
______
Textbooks (Fall 2016)

18.100P Real Analysis
(New)
______

Undergrad (Spring)
Prereq: Calculus II (GIR); or 18.014 andCoreq: Calculus II (GIR)
Units: 4-0-11
Credit cannot also be received for18.1001,18.100A,18.100B,18.100Q
______

18.100Q Real Analysis
(18.100C)
______

Undergrad (Fall)
Prereq: Calculus II (GIR); or 18.014 andCoreq: Calculus II (GIR)
Units: 4-0-11
Credit cannot also be received for18.1001,18.1002,18.100A,18.100B,18.100P
Lecture: TR9.30-11 (2-131) Recitation: F10 (2-131) or F3 (2-131) +final
______
Four options offered, each covering fundamentals of mathematical analysis: convergence of sequences and series, continuity, differentiability, Riemann integral, sequences and series of functions, uniformity, interchange of limit operations. Each option shows the utility of abstract concepts and teaches understanding and construction of proofs. Option A: Proofs and definitions are less abstract. Gives applications where possible. Concerned primarily with the real line. Option B: More demanding; for students with more mathematical maturity. Places more emphasis on point-set topology and n-space. Option P: 15-unit (4-0-11) variant of Option A, with further instruction and practice in written communication. Option Q: 15-unit (4-0-11) variant of Option B, with further instruction and practice in written communication. Enrollment limited in Options P and Q.
Fall:18.100A: A. P. Mattuck
18.100B: D. Jerison
18.100Q: B. Wilson

Spring:18.100A: R. Casals
18.100B: A. Lawrie
18.100P: T. Beck

Textbooks (Fall 2016)

18.101 Analysis and Manifolds
______

Undergrad (Fall)
(Subject meets with18.1011)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.101/
Lecture: MWF11 (2-143) +final
______
Introduction to the theory of manifolds: vector fields and densities on manifolds, integral calculus in the manifold setting and the manifold version of the divergence theorem. 18.901 helpful but not required.
V. W. Guillemin
Textbooks (Fall 2016)

18.1011 Analysis and Manifolds
______

Graduate (Fall)
(Subject meets with18.101)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
Lecture: MWF11 (2-143) +final
______
Introduction to the theory of manifolds: vector fields and densities on manifolds, integral calculus in the manifold setting and the manifold version of the divergence theorem. 18.9011 helpful but not required. Students in Course 18 must register for the undergraduate version, 18.101.
V. W. Guillemin
No textbook information available

18.102 Introduction to Functional Analysis
______

Undergrad (Spring)
(Subject meets with18.1021)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.102
______
Normed spaces, completeness, functionals, Hahn-Banach theorem, duality, operators. Lebesgue measure, measurable functions, integrability, completeness of L-p spaces. Hilbert space. Compact, Hilbert-Schmidt and trace class operators. Spectral theorem.
R. B. Melrose

18.1021 Introduction to Functional Analysis
______

Graduate (Spring)
(Subject meets with18.102)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
______
Normed spaces, completeness, functionals, Hahn-Banach theorem, duality, operators. Lebesgue measure, measurable functions, integrability, completeness of L-p spaces. Hilbert space. Compact, Hilbert-Schmidt and trace class operators. Spectral theorem. Students in Course 18 must register for the undergraduate version, 18.102.
R. B. Melrose

18.103 Fourier Analysis: Theory and Applications
______

Undergrad (Fall)
(Subject meets with18.1031)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.103
Lecture: MWF12 (2-139) +final
______
Roughly half the subject devoted to the theory of the Lebesgue integral with applications to probability, and half to Fourier series and Fourier integrals.
A. Lawrie
Textbooks (Fall 2016)

18.1031 Fourier Analysis: Theory and Applications
______

Graduate (Fall)
(Subject meets with18.103)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
Lecture: MWF12 (2-139) +final
______
Roughly half the subject devoted to the theory of the Lebesgue integral with applications to probability, and half to Fourier series and Fourier integrals. Students in Course 18 must register for the undergraduate version, 18.103.
A. Lawrie
Textbooks (Fall 2016)

18.104 Seminar in Analysis
______

Undergrad (Spring)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q
Units: 3-0-9
URL: http://math.mit.edu/~datchev/18.104/18.104.html
______
Students present and discuss material from books or journals. Topics vary from year to year. Instruction and practice in written and oral communication provided. Enrollment limited.
D. Jerison

18.112 Functions of a Complex Variable
______

Undergrad (Fall)
(Subject meets with18.1121)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.112
Lecture: MWF10 (56-154) +final
______
Studies the basic properties of analytic functions of one complex variable. Conformal mappings and the Poincare model of non-Euclidean geometry. Cauchy-Goursat theorem and Cauchy integral formula. Taylor and Laurent decompositions. Singularities, residues and computation of integrals. Harmonic functions and Dirichlet's problem for the Laplace equation. The partial fractions decomposition. Infinite series and infinite product expansions. The Gamma function. The Riemann mapping theorem. Elliptic functions.
T. Beck
Textbooks (Fall 2016)

18.1121 Functions of a Complex Variable
______

Graduate (Fall)
(Subject meets with18.112)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
Lecture: MWF10 (56-154) +final
______
Studies the basic properties of analytic functions of one complex variable. Conformal mappings and the Poincare model of non-Euclidean geometry. Cauchy-Goursat theorem and Cauchy integral formula. Taylor and Laurent decompositions. Singularities, residues and computation of integrals. Harmonic functions and Dirichlet's problem for the Laplace equation. The partial fractions decomposition. Infinite series and infinite product expansions. The Gamma function. The Riemann mapping theorem. Elliptic functions. Students in Course 18 must register for the undergraduate version, 18.112.
T. Beck
No textbook information available

18.116 Riemann Surfaces
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 18.112
Units: 3-0-9
Lecture: MWF9 (2-136)
______
Riemann surfaces, uniformization, Riemann-Roch Theorem. Theory of elliptic functions and modular forms. Some applications, such as to number theory.
R. Casals
No required or recommended textbooks

18.117 Topics in Several Complex Variables
______

Not offered academic year 2017-2018Graduate (Spring) Can be repeated for credit
Prereq: 18.112, 18.965
Units: 3-0-9
______
Harmonic theory on complex manifolds, Hodge decomposition theorem, Hard Lefschetz theorem. Vanishing theorems. Theory of Stein manifolds. As time permits students also study holomorphic vector bundles on Kahler manifolds.
B. Poonen

18.125 Measure Theory and Analysis
______

Graduate (Spring)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q
Units: 3-0-9
URL: http://math.mit.edu/classes/18.125/
______
Provides a rigorous introduction to Lebesgue's theory of measure and integration. Covers material that is essential in analysis, probability theory, and differential geometry.
S. Becker-Kahn

18.137 Topics in Geometric Partial Differential Equations
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: Permission of Instructor
Units: 3-0-9
______
Topics vary from year to year.
Information: R. B. Melrose

18.152 Introduction to Partial Differential Equations
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with18.1521)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.152
______
Introduces three main types of partial differential equations: diffusion, elliptic, and hyperbolic. Includes mathematical tools, real-world examples and applications, such as the Black-Scholes equation, the European options problem, water waves, scalar conservation laws, first order equations and traffic problems.
J. Speck

18.1521 Introduction to Partial Differential Equations
______

Not offered academic year 2016-2017Graduate (Spring)
(Subject meets with18.152)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
______
Introduces three main types of partial differential equations: diffusion, elliptic, and hyperbolic. Includes mathematical tools, real-world examples and applications, such as the Black-Scholes equation, the European options problem, water waves, scalar conservation laws, first order equations and traffic problems. Students in Course 18 must register for the undergraduate version, 18.152.
J. Speck

18.155 Differential Analysis I
______

Graduate (Fall)
Prereq: 18.102 or 18.103
Units: 3-0-9
URL: http://math.mit.edu/classes/18.155
Lecture: TR11-12.30 (2-135)
______
R. B. Melrose
No required or recommended textbooks

18.156 Differential Analysis II
______

Graduate (Spring)
Prereq: 18.155
Units: 3-0-9
URL: http://math.mit.edu/classes/18.156
______
Fall: Review of Lebesgue integration. Lp spaces. Distributions. Fourier transform. Sobolev spaces. Spectral theorem, discrete and continuous spectrum. Homogeneous distributions. Fundamental solutions for elliptic, hyperbolic and parabolic differential operators. Spring: Variable coefficient elliptic, parabolic and hyperbolic partial differential equations. 18.112 recommended for 18.155.
Fall:R. B. Melrose
Spring:S. Dyatlov

18.157 Introduction to Microlocal Analysis
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 18.155
Units: 3-0-9
URL: http://math.mit.edu/classes/18.157
______
The semi-classical theory of partial differential equations. Discussion of Pseudodifferential operators, Fourier integral operators, asymptotic solutions of partial differential equations, and the spectral theory of Schroedinger operators from the semi-classical perspective. Heavy emphasis placed on the symplectic geometric underpinnings of this subject.
V. W. Guillemin

18.158 Topics in Differential Equations
______

Graduate (Spring) Can be repeated for credit
Prereq: 18.157
Units: 3-0-9
URL: http://math.mit.edu/classes/18.158/
______
Topics vary from year to year.
G. Staffilani

18.175 Theory of Probability
______

Graduate (Fall)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q
Units: 3-0-9
URL: http://math.mit.edu/classes/18.175
Lecture: TR2.30-4 (2-131)
______
Sums of independent random variables, central limit phenomena, infinitely divisible laws, Levy processes, Brownian motion, conditioning, and martingales. Prior exposure to probability (e.g., 18.600) recommended.
S. Sheffield
No textbook information available

18.176 Stochastic Calculus
______

Graduate (Spring)
Prereq: 18.175
Units: 3-0-9
______
Introduction to stochastic processes with an emphasis on their relationship to other branches of analysis, especially partial differential equations. Topics include Brownian motion, continuous parameter martingales, Ito's theory of stochastic differential equations, Levy processes, and may also address Malliavin''s calculus. Students should have familiarity with Lebesgue integration and its application to probability, as well knowledge of the Fourier transform and other basic tools of analysis.
D. W. Stroock

18.177 Topics in Stochastic Processes
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: 18.175
Units: 3-0-9
URL: http://math.mit.edu/classes/18.177
Lecture: TR9.30-11 (2-142)
______
Topics vary from year to year.
Fall:V. Gorin
Spring:E. Mossel
No required or recommended textbooks

18.199 Graduate Analysis Seminar
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
Studies original papers in differential analysis and differential equations. Intended for first- and second-year graduate students. Permission must be secured in advance.
V. W. Guillemin

Discrete Applied Mathematics

18.200 Principles of Discrete Applied Mathematics
______

Undergrad (Fall)
Prereq: Calculus II (GIR)
Units: 4-0-11
Credit cannot also be received for18.200A
Lecture: MWF12 (2-190) Recitation: R10 (2-132) or R12 (2-143) or R1 (2-143) or R3 (2-142)
______
Study of illustrative topics in discrete applied mathematics, including sorting algorithms, probability theory, information theory, coding theory, secret codes, generating functions, and linear programming. Instruction and practice in written communication provided. Enrollment limited.
M. X. Goemans
No required or recommended textbooks

18.200A Principles of Discrete Applied Mathematics
______

Undergrad (Spring)
Prereq: Calculus II (GIR)
Units: 3-0-9
Credit cannot also be received for18.200
______
Study of illustrative topics in discrete applied mathematics, including sorting algorithms, probability theory, information theory, coding theory, secret codes, generating functions, and linear programming.
P. W. Shor

18.204 Undergraduate Seminar in Discrete Mathematics
______

Undergrad (Fall, Spring)
Prereq: 18.200 or 18.062; 18.06, 18.700, or 18.701; or permission of instructor
Units: 3-0-9
Lecture: MWF2 (2-132, 2-151)
______
Seminar in combinatorics, graph theory, and discrete mathematics in general. Participants read and present papers from recent mathematics literature. Instruction and practice in written and oral communication provided. Enrollment limited.
Fall:T. McConville
Spring:Y. Wang
No required or recommended textbooks

18.211 Combinatorial Analysis
______

Undergrad (Fall)
Prereq: Calculus II (GIR); 18.06, 18.700, or 18.701
Units: 3-0-9
Lecture: MWF1 (2-132) +final
______
Combinatorial problems and methods for their solution. Enumeration, generating functions, recurrence relations, construction of bijections. Introduction to graph theory. Prior experience with abstraction and proofs is helpful.
M. Rahman
Textbooks (Fall 2016)

18.212 Algebraic Combinatorics
______

Undergrad (Spring)
Prereq: 18.701 or 18.703
Units: 3-0-9
______
Applications of algebra to combinatorics. Topics include walks in graphs, the Radon transform, groups acting on posets, Young tableaux, electrical networks.
T. McConville

18.217 Combinatorial Theory
______

Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
Lecture: MWF11 (2-131)
______
Content varies from year to year.
R. P. Stanley
Textbooks (Fall 2016)

18.218 Topics in Combinatorics
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
Topics vary from year to year.
A. Postnikov

18.219 Seminar in Combinatorics
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
Content varies from year to year. Readings from current research papers in combinatorics. Topics to be chosen and presented by the class.
J. Fox

Continuous Applied Mathematics

18.300 Principles of Continuum Applied Mathematics
______

Undergrad (Spring)
Prereq: Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9
______
Covers fundamental concepts in continuous applied mathematics. Applications from traffic flow, fluids, elasticity, granular flows, etc. Also covers continuum limit; conservation laws, quasi-equilibrium; kinematic waves; characteristics, simple waves, shocks; diffusion (linear and nonlinear); numerical solution of wave equations; finite differences, consistency, stability; discrete and fast Fourier transforms; spectral methods; transforms and series (Fourier, Laplace). Additional topics may include sonic booms, Mach cone, caustics, lattices, dispersion and group velocity. Uses MATLAB computing environment.
L. Faria

18.303 Linear Partial Differential Equations: Analysis and Numerics
______

Undergrad (Fall)
Prereq: 18.06 or 18.700
Units: 3-0-9
URL: http://math.mit.edu/classes/18.303
Lecture: MWF2 (4-159)
______
Provides students with the basic analytical and computational tools of linear partial differential equations (PDEs) for practical applications in science and engineering, including heat/diffusion, wave, and Poisson equations. Analytics emphasize the viewpoint of linear algebra and the analogy with finite matrix problems. Studies operator adjoints and eigenproblems, series solutions, Green's functions, and separation of variables. Numerics focus on finite-difference and finite-element techniques to reduce PDEs to matrix problems, including stability and convergence analysis and implicit/explicit timestepping. Some programming required for homework and final project.
S. G. Johnson
Textbooks (Fall 2016)

18.305 Advanced Analytic Methods in Science and Engineering
______

Graduate (Fall)
Prereq: 18.04, 18.075, or 18.112
Units: 3-0-9
URL: http://math.mit.edu/18.305/
Lecture: MWF12 (2-135)
______
Covers expansion around singular points: the WKB method on ordinary and partial differential equations; the method of stationary phase and the saddle point method; the two-scale method and the method of renormalized perturbation; singular perturbation and boundary-layer techniques; WKB method on partial differential equations.
H. Cheng
Textbooks (Fall 2016)

18.306 Advanced Partial Differential Equations with Applications
______

Graduate (Spring)
Prereq: 18.03 or 18.034; 18.04, 18.075, or 18.112
Units: 3-0-9
URL: http://math.mit.edu/classes/18.306
______
Concepts and techniques for partial differential equations, especially nonlinear. Diffusion, dispersion and other phenomena. Initial and boundary value problems. Normal mode analysis, Green's functions, and transforms. Conservation laws, kinematic waves, hyperbolic equations, characteristics shocks, simple waves. Geometrical optics, caustics. Free-boundary problems. Dimensional analysis. Singular perturbation, boundary layers, homogenization. Variational methods. Solitons. Applications from fluid dynamics, materials science, optics, traffic flow, etc.
R. R. Rosales

18.327 Topics in Applied Mathematics
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/1.130/
______
Topics vary from year to year.
L. Demanet

18.330 Introduction to Numerical Analysis
______

Undergrad (Spring)
Prereq: Calculus II (GIR); 18.03 or 18.034
Units: 3-0-9
URL: http://math.mit.edu/classes/18.330/
______
Basic techniques for the efficient numerical solution of problems in science and engineering. Root finding, interpolation, approximation of functions, integration, differential equations, direct and iterative methods in linear algebra. Knowledge of programming in Fortran, C, or MATLAB helpful.
H. Reid

18.335[J] Introduction to Numerical Methods
______

Graduate (Spring)
(Same subject as6.337[J])
Prereq: 18.03 or 18.034; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.335
______
Advanced introduction to numerical linear algebra and other central algorithms of scientific computation. Topics include direct and iterative methods for linear systems, eigenvalue and QR/SVD factorizations, stability and accuracy, floating-point arithmetic, sparse matrices, preconditioning, and the memory considerations underlying modern linear-algebra software. Techniques for local and global nonlinear optimization, including quasi-Newton methods, trust regions, branch-and-bound, and multistart algorithms. Chebyshev approximations, numerical integration, and FFTs. A modern high-level language, Julia, is introduced for problem sets.
W. Shin

18.336[J] Fast Methods for Partial Differential and Integral Equations
______

Graduate (Fall)
(Same subject as6.335[J])
Prereq: 6.336, 16.920, 18.085, 18.335, or permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.336
Lecture: MW9.30-11 (2-146)
______
Unified introduction to the theory and practice of modern, near linear-time, numerical methods for large-scale partial-differential and integral equations. Topics include preconditioned iterative methods; generalized Fast Fourier Transform and other butterfly-based methods; multiresolution approaches, such as multigrid algorithms and hierarchical low-rank matrix decompositions; and low and high frequency Fast Multipole Methods. Example applications include aircraft design, cardiovascular system modeling, electronic structure computation, and tomographic imaging.
C. Perez
No required or recommended textbooks

18.337[J] Parallel Computing
______

Graduate (Fall)
(Same subject as6.338[J])
Prereq: 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://beowulf.csail.mit.edu/18.337/index.html
Lecture: MW2-3.30 (4-237)
______
Interdisciplinary introduction to computing with Julia. Covers scientific computing and data analysis problems. Combines knowledge from computer science and computational science illustrating Julia's new approach to scientific computing. Sample scientific computing topics include dense and sparse linear algebra, Fourier transforms, data handling, and N-body problems. Provides direct experience with programming traditional-style supercomputing as well as working with modern cloud computing stacks.
A. Edelman
No textbook information available

18.338 Eigenvalues of Random Matrices
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.701 or permission of instructor
Units: 3-0-9
URL: http://www.mit.edu/~18.338/
______
Covers the modern main results of random matrix theory as it is currently applied in engineering and science. Topics include matrix calculus for finite and infinite matrices (e.g., Wigner's semi-circle and Marcenko-Pastur laws), free probability, random graphs, combinatorial methods, matrix statistics, stochastic operators, passage to the continuum limit, moment methods, and compressed sensing. Knowledge of MATLAB hepful, but not required.
A. Edelman

18.352[J] Nonlinear Dynamics: The Natural Environment
______

Undergrad (Spring)
(Same subject as12.009[J])
Prereq: Physics I (GIR), Calculus II (GIR);Coreq: 18.03
Units: 3-0-9
______
Analyzes cooperative processes that shape the natural environment, now and in the geologic past. Emphasizes the development of theoretical models that relate the physical and biological worlds, the comparison of theory to observational data, and associated mathematical methods. Topics include carbon cycle dynamics; ecosystem structure, stability and complexity; mass extinctions; biosphere-geosphere coevolution; and climate change. Employs techniques such as stability analysis; scaling; null model construction; time series and network analysis.
D. H. Rothman

18.353[J] Nonlinear Dynamics: Chaos
______

Undergrad (Fall)
(Same subject as 2.050[J],12.006[J])
Prereq: 18.03 or 18.034; Physics II (GIR)
Units: 3-0-9
Lecture: TR1-2.30 (2-105)
______
Introduction to nonlinear dynamics and chaos in dissipative systems. Forced and parametric oscillators. Phase space. Periodic, quasiperiodic, and aperiodic flows. Sensitivity to initial conditions and strange attractors. Lorenz attractor. Period doubling, intermittency, and quasiperiodicity. Scaling and universality. Analysis of experimental data: Fourier transforms, Poincare sections, fractal dimension, and Lyapunov exponents. Applications to mechanical systems, fluid dynamics, physics, geophysics, and chemistry. See 12.207J/18.354J for Nonlinear Dynamics: Continuum Systems.
P-T. Brun
Textbooks (Fall 2016)

18.354[J] Nonlinear Dynamics: Continuum Systems
______

Undergrad (Spring)
(Same subject as1.062[J],12.207[J])
(Subject meets with18.3541)
Prereq: 18.03 or 18.034; Physics II (GIR)
Units: 3-0-9
URL: http://math.mit.edu/classes/18.354/
______
General mathematical principles of continuum systems. From microscopic to macroscopic descriptions in the form of linear or nonlinear (partial) differential equations. Exact solutions, dimensional analysis, calculus of variations and singular perturbation methods. Stability, waves and pattern formation in continuum systems. Subject matter illustrated using natural fluid and solid systems found, for example, in geophysics and biology.
P. Pearce

18.3541 Nonlinear Dynamics: Continuum Systems
______

Graduate (Spring)
(Subject meets with1.062[J],12.207[J],18.354[J])
Prereq: 18.03 or 18.034; Physics II (GIR)
Units: 3-0-9
______
General mathematical principles of continuum systems. From microscopic to macroscopic descriptions in the form of linear or nonlinear (partial) differential equations. Exact solutions, dimensional analysis, calculus of variations and singular perturbation methods. Stability, waves and pattern formation in continuum systems. Subject matter illustrated using natural fluid and solid systems found, for example, in geophysics and biology. Students in Courses 1, 12, and 18 must register for undergraduate version, 18.354.
P. Pearce

18.355 Fluid Mechanics
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 18.354, 2.25, or 12.800
Units: 3-0-9
Lecture: MW2-3.30 (2-135)
______
Topics include the development of Navier-Stokes equations, inviscid flows, boundary layers, lubrication theory, Stokes flows, and surface tension. Fundamental concepts illustrated through problems drawn from a variety of areas, including geophysics, biology, and the dynamics of sport. Particular emphasis on the interplay between dimensional analysis, scaling arguments, and theory. Includes classroom and laboratory demonstrations.
J. W. Bush
No required or recommended textbooks

18.357 Interfacial Phenomena
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.354, 18.355, 12.800, 2.25, or permission of instructor
Units: 3-0-9
______
Fluid systems dominated by the influence of interfacial tension. Elucidates the roles of curvature pressure and Marangoni stress in a variety of hydrodynamic settings. Particular attention to drops and bubbles, soap films and minimal surfaces, wetting phenomena, water-repellency, surfactants, Marangoni flows, capillary origami and contact line dynamics. Theoretical developments are accompanied by classroom demonstrations. Highlights the role of surface tension in biology.
J. W. Bush

18.358[J] Nonlinear Dynamics and Turbulence
(New)
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as1.686[J])
(Subject meets with1.068)
Prereq: 18.355 or permission of instructor
Units: 3-0-9
______
Reviews theoretical notions of nonlinear dynamics, instabilities, and waves with applications in fluid dynamics. Discusses hydrodynamic instabilities leading to flow destabilization and transition to turbulence. Focuses on physical turbulence and mixing from homogenous isotropic turbulence. Also covers topics such as rotating and stratified flows as they arise in the environment, wave-turbulence, and point source turbulent flows. Students taking graduate version complete additional assignments.
L. Bourouiba

18.369 Mathematical Methods in Nanophotonics
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.305 or permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.369
______
High-level approaches to understanding complex optical media, structured on the scale of the wavelength, that are not generally analytically soluable. The basis for understanding optical phenomena such as photonic crystals and band gaps, anomalous diffraction, mechanisms for optical confinement, optical fibers (new and old), nonlinearities, and integrated optical devices. Methods covered include linear algebra and eigensystems for Maxwell's equations, symmetry groups and representation theory, Bloch's theorem, numerical eigensolver methods, time and frequency-domain computation, perturbation theory, and coupled-mode theories.
S. G. Johnson

18.376[J] Wave Propagation
______

Graduate (Spring)
(Same subject as1.138[J],2.062[J])
Prereq: 2.003, 18.075
Units: 3-0-9
URL: http://math.mit.edu/classes/18.376/
______
Theoretical concepts and analysis of wave problems in science and engineering with examples chosen from elasticity, acoustics, geophysics, hydrodynamics, blood flow, nondestructive evaluation, and other applications. Progressive waves, group velocity and dispersion, energy density and transport. Reflection, refraction and transmission of plane waves by an interface. Mode conversion in elastic waves. Rayleigh waves. Waves due to a moving load. Scattering by a two-dimensional obstacle. Reciprocity theorems. Parabolic approximation. Waves on the sea surface. Capillary-gravity waves. Wave resistance. Radiation of surface waves. Internal waves in stratified fluids. Waves in rotating media. Waves in random media.
T. R. Akylas, R. R. Rosales

18.377[J] Nonlinear Dynamics and Waves
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as1.685[J],2.034[J])
Prereq: Permission of instructor
Units: 3-0-9
______
A unified treatment of nonlinear oscillations and wave phenomena with applications to mechanical, optical, geophysical, fluid, electrical and flow-structure interaction problems. Nonlinear free and forced vibrations; nonlinear resonances; self-excited oscillations; lock-in phenomena. Nonlinear dispersive and nondispersive waves; resonant wave interactions; propagation of wave pulses and nonlinear Schrodinger equation. Nonlinear long waves and breaking; theory of characteristics; the Korteweg-de Vries equation; solitons and solitary wave interactions. Stability of shear flows. Some topics and applications may vary from year to year.
T. R. Akylas, R. R. Rosales

18.384 Undergraduate Seminar in Physical Mathematics
______

Undergrad (Fall)
Prereq: 18.300, 18.353, 18.354, or permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.384
Lecture: TR11-12.30 (2-151)
______
Covers the mathematical modeling of physical systems, with emphasis on the reading and presentation of papers. Addresses a broad range of topics, with particular focus on macroscopic physics and continuum systems: fluid dynamics, solid mechanics, and biophysics. Instruction and practice in written and oral communication provided. Enrollment limited.
L. Faria
No required or recommended textbooks

18.385[J] Nonlinear Dynamics and Chaos
______

Not offered academic year 2017-2018Graduate (Fall)
(Same subject as2.036[J])
Prereq: 18.03 or 18.034
Units: 3-0-9
URL: http://math.mit.edu/classes/18.385
Lecture: TR11-12.30 (2-136)
______
Introduction to the theory of nonlinear dynamical systems with applications from science and engineering. Local and global existence of solutions, dependence on initial data and parameters. Elementary bifurcations, normal forms. Phase plane, limit cycles, relaxation oscillations, Poincare-Bendixson theory. Floquet theory. Poincare maps. Averaging. Near-equilibrium dynamics. Synchronization. Introduction to chaos. Universality. Strange attractors. Lorenz and Rossler systems. Hamiltonian dynamics and KAM theory. Uses MATLAB computing environment.
R. R. Rosales
Textbooks (Fall 2016)

18.395 Group Theory with Applications to Physics
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 8.321
Units: 3-0-9
______
Selection of topics from the theory of finite groups, Lie groups, and group representations, motivated by quantum mechanics and particle physics. 8.322 and 8.323 helpful.
D. Z. Freedman

18.396[J] Supersymmetric Quantum Field Theories
______

Graduate (Fall) Can be repeated for credit
Not offered regularly; consult department
(Same subject as8.831[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Topics selected from the following: SUSY algebras and their particle representations; Weyl and Majorana spinors; Lagrangians of basic four-dimensional SUSY theories, both rigid SUSY and supergravity; supermultiplets of fields and superspace methods; renormalization properties, and the non-renormalization theorem; spontaneous breakdown of SUSY; and phenomenological SUSY theories. Some prior knowledge of Noether's theorem, derivation and use of Feynman rules, l-loop renormalization, and gauge theories is essential.
D. Z. Freedman

Theoretical Computer Science

18.400[J] Automata, Computability, and Complexity
______

Undergrad (Spring)
(Same subject as6.045[J])
Prereq: 6.042
Units: 4-0-8
URL: http://math.mit.edu/classes/18.400
______
Provides an introduction to some of the central ideas of theoretical computer science, including circuits, finite automata, Turing machines and computability, efficient algorithms and reducibility, the P versus NP problem, NP-completeness, the power of randomness, cryptography, computational learning theory, and quantum computing. Examines the classes of problems that can and cannot be solved in various computational models.
S. Aaronson

18.404 Theory of Computation
______

Undergrad (Fall)
(Subject meets with6.840[J],18.4041[J])
Prereq: 18.200 or 18.062J
Units: 4-0-8
URL: http://math.mit.edu/classes/18.404
1st mtg Sept 8 at 2.30. Room 54-100. Lecture: TR2.30-4 (2-190) Recitation: F12 (2-143) or F1 (2-139) or F2 (2-139) +final
______
A more extensive and theoretical treatment of the material in 6.045J/18.400J, emphasizing computability and computational complexity theory. Regular and context-free languages. Decidable and undecidable problems, reducibility, recursive function theory. Time and space measures on computation, completeness, hierarchy theorems, inherently complex problems, oracles, probabilistic computation, and interactive proof systems.
M. Sipser
Textbooks (Fall 2016)

18.4041[J] Theory of Computation
______

Graduate (Fall)
(Same subject as6.840[J])
(Subject meets with18.404)
Prereq: 18.200 or 18.062J
Units: 4-0-8
1st mtg Sept 8 at 2.30. Room 54-100. Lecture: TR2.30-4 (2-190) Recitation: F12 (2-143) or F1 (2-139) or F2 (2-139) +final
______
A more extensive and theoretical treatment of the material in 6.045J/18.400J, emphasizing computability and computational complexity theory. Regular and context-free languages. Decidable and undecidable problems, reducibility, recursive function theory. Time and space measures on computation, completeness, hierarchy theorems, inherently complex problems, oracles, probabilistic computation, and interactive proof systems. Students in Course 18 must register for the undergraduate version, 18.404.
M. Sipser
Textbooks (Fall 2016)

18.405[J] Advanced Complexity Theory
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as6.841[J])
Prereq: 18.404
Units: 3-0-9
______
Current research topics in computational complexity theory. Nondeterministic, alternating, probabilistic, and parallel computation models. Boolean circuits. Complexity classes and complete sets. The polynomial-time hierarchy. Interactive proof systems. Relativization. Definitions of randomness. Pseudo-randomness and derandomizations. Interactive proof systems and probabilistically checkable proofs.
D. Moshkovitz

18.408 Topics in Theoretical Computer Science
______

Not offered academic year 2017-2018Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
Lecture: F9-12 (4-163)
______
Study of areas of current interest in theoretical computer science. Topics vary from term to term.
Information: M. X. Goemans
No required or recommended textbooks

18.410[J] Design and Analysis of Algorithms
______

Undergrad (Fall, Spring)
(Same subject as6.046[J])
Prereq: 6.006
Units: 4-0-8
URL: http://math.mit.edu/classes/18.410
Lecture: TR11-12.30 (32-123) Recitation: F10 (4-159) or F11 (4-159, 4-149, 36-156) or F12 (36-156, 4-159) or F1 (4-159, 4-149) or F2 (35-308) or F3 (35-308) +final
______
Techniques for the design and analysis of efficient algorithms, emphasizing methods useful in practice. Topics include sorting; search trees, heaps, and hashing; divide-and-conquer; dynamic programming; greedy algorithms; amortized analysis; graph algorithms; and shortest paths. Advanced topics may include network flow; computational geometry; number-theoretic algorithms; polynomial and matrix calculations; caching; and parallel computing.
E. Demaine, M. Goemans
Textbooks (Fall 2016)

18.415[J] Advanced Algorithms
______

Graduate (Fall)
(Same subject as6.854[J])
Prereq: 6.041B, 6.042, or 18.600; 6.046
Units: 5-0-7
URL: http://theory.lcs.mit.edu/classes/6.854/
Lecture: MWF2.30-4 (32-141)
______
First-year graduate subject in algorithms. Emphasizes fundamental algorithms and advanced methods of algorithmic design, analysis, and implementation. Surveys a variety of computational models and the algorithms for them. Data structures, network flows, linear programming, computational geometry, approximation algorithms, online algorithms, parallel algorithms, external memory, streaming algorithms.
A. Moitra, D. R. Karger
No required or recommended textbooks

18.416[J] Randomized Algorithms
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as6.856[J])
Prereq: 6.854J, 6.041B or 6.042J
Units: 5-0-7
______
Studies how randomization can be used to make algorithms simpler and more efficient via random sampling, random selection of witnesses, symmetry breaking, and Markov chains. Models of randomized computation. Data structures: hash tables, and skip lists. Graph algorithms: minimum spanning trees, shortest paths, and minimum cuts. Geometric algorithms: convex hulls, linear programming in fixed or arbitrary dimension. Approximate counting; parallel algorithms; online algorithms; derandomization techniques; and tools for probabilistic analysis of algorithms.
D. R. Karger

18.417 Introduction to Computational Molecular Biology
______

Graduate (Fall)
Not offered regularly; consult department
Prereq: 6.01, 6.006, or permission of instructor
Units: 3-0-9
URL: http://www-math.mit.edu/18.417/
______
Introduces the basic computational methods used to model and predict the structure of biomolecules (proteins, DNA, RNA). Covers classical techniques in the field (molecular dynamics, Monte Carlo, dynamic programming) to more recent advances in analyzing and predicting RNA and protein structure, ranging from Hidden Markov Models and 3-D lattice models to attribute Grammars and tree Grammars.
Information: B. Berger

18.418 Topics in Computational Molecular Biology
______

Graduate (Spring) Can be repeated for credit
Prereq: 18.417, 6.047, or permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.418
______
Covers current research topics in computational molecular biology. Recent research papers presented from leading conferences such as the SIGACT International Conference on Computational Molecular Biology (RECOMB). Topics include original research (both theoretical and experimental) in comparative genomics, sequence and structure analysis, molecular evolution, proteomics, gene expression, transcriptional regulation, and biological networks. Recent research by course participants also covered. Participants will be expected to present either group or individual projects to the class.
B. Berger

18.424 Seminar in Information Theory
______

Undergrad (Fall)
Prereq: 18.05, 18.600, or 6.041B; 18.06, 18.700, or 18.701
Units: 3-0-9
Lecture: TR11-12.30 (2-142)
______
Considers various topics in information theory, including data compression, Shannon's Theorems, and error-correcting codes. Students present and discuss the subject matter. Instruction and practice in written and oral communication provided. Enrollment limited.
P. W. Shor
Textbooks (Fall 2016)

18.425[J] Cryptography and Cryptanalysis
______

Graduate (Spring)
(Same subject as6.875[J])
Prereq: 6.046J
Units: 3-0-9
______
A rigorous introduction to modern cryptography. Emphasis on the fundamental cryptographic primitives of public-key encryption, digital signatures, pseudo-random number generation, and basic protocols and their computational complexity requirements.
S. Goldwasser, S. Micali

18.434 Seminar in Theoretical Computer Science
______

Undergrad (Spring)
Prereq: 18.410
Units: 3-0-9
URL: http://math.mit.edu/classes/18.434
______
Topics vary from year to year. Students present and discuss the subject matter. Instruction and practice in written and oral communication provided. Enrollment limited.
Information: P. Shor

18.435[J] Quantum Computation
______

Graduate (Fall)
(Same subject as2.111[J],8.370[J])
Prereq: Permission of instructor
Units: 3-0-9
Lecture: TR1-2.30 (4-370) +final
______
Provides an introduction to the theory and practice of quantum computation. Topics covered: physics of information processing; quantum algorithms including the factoring algorithm and Grover's search algorithm; quantum error correction; quantum communication and cryptography. Knowledge of quantum mechanics helpful but not required.
I. Chuang, E. Farhi, S. Lloyd, P. Shor
Textbooks (Fall 2016)

18.436[J] Quantum Information Science
______

Graduate (Spring)
(Same subject as6.443[J],8.371[J])
Prereq: 18.435
Units: 3-0-9
______
Examines quantum computation and quantum information. Topics include quantum circuits, the quantum Fourier transform and search algorithms, the quantum operations formalism, quantum error correction, Calderbank-Shor-Steane and stabilizer codes, fault tolerant quantum computation, quantum data compression, quantum entanglement, capacity of quantum channels, and quantum cryptography and the proof of its security. Prior knowledge of quantum mechanics required.
I. Chuang

18.437[J] Distributed Algorithms
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as6.852[J])
Prereq: 6.046
Units: 3-0-9
URL: http://theory.csail.mit.edu/classes/6.852/
Subject Cancelled Subject Cancelled
______
Design and analysis of concurrent algorithms, emphasizing those suitable for use in distributed networks. Process synchronization, allocation of computational resources, distributed consensus, distributed graph algorithms, election of a leader in a network, distributed termination, deadlock detection, concurrency control, communication, and clock synchronization. Special consideration given to issues of efficiency and fault tolerance. Formal models and proof methods for distributed computation.
N. A. Lynch

18.453 Combinatorial Optimization
______

Not offered academic year 2017-2018Undergrad (Spring)
(Subject meets with18.4531)
Prereq: 18.06, 18.700, or 18.701
Units: 3-0-9
______
Thorough treatment of linear programming and combinatorial optimization. Topics include matching theory, network flow, matroid optimization, and how to deal with NP-hard optimization problems. Prior exposure to discrete mathematics (such as 18.200) helpful.
M. X. Goemans

18.4531 Combinatorial Optimization
______

Not offered academic year 2017-2018Graduate (Spring)
(Subject meets with18.453)
Prereq: 18.06, 18.700, or 18.701
Units: 3-0-9
______
Thorough treatment of linear programming and combinatorial optimization. Topics include matching theory, network flow, matroid optimization, and how to deal with NP-hard optimization problems. Prior exposure to discrete mathematics (such as 18.200) helpful. Students in Course 18 must register for the undergraduate version, 18.453.
M. X. Goemans

18.455 Advanced Combinatorial Optimization
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.453 or permission of instructor
Units: 3-0-9
______
Advanced treatment of combinatorial optimization with an emphasis on combinatorial aspects. Non-bipartite matchings, submodular functions, matroid intersection/union, matroid matching, submodular flows, multicommodity flows, packing and connectivity problems, and other recent developments.
M. X. Goemans


left arrow|18.01-18.499|18.50-18.THG|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 18: Mathematics
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Course 18: Mathematics
Fall 2016


Logic

18.504 Seminar in Logic
______

Not offered academic year 2017-2018Undergrad (Spring)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.510, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.504
______
Students present and discuss the subject matter taken from current journals or books. Topics vary from year to year. Instruction and practice in written and oral communication provided. Enrollment limited.
H. Cohn

18.510 Introduction to Mathematical Logic and Set Theory
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: None
Units: 3-0-9
URL: http://math.mit.edu/classes/18.510
______
Propositional and predicate logic. Zermelo-Fraenkel set theory. Ordinals and cardinals. Axiom of choice and transfinite induction. Elementary model theory: completeness, compactness, and Lowenheim-Skolem theorems. Godel's incompleteness theorem.
H. Cohn

18.515 Mathematical Logic
______

Graduate (Spring)
Not offered regularly; consult department
Prereq: Permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.515
______
More rigorous treatment of basic mathematical logic, Godel's theorems, and Zermelo-Fraenkel set theory. First-order logic. Models and satisfaction. Deduction and proof. Soundness and completeness. Compactness and its consequences. Quantifier elimination. Recursive sets and functions. Incompleteness and undecidability. Ordinals and cardinals. Set-theoretic formalization of mathematics.
Information: B. Poonen

Probability and Statistics

18.600 Probability and Random Variables
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR)
Units: 3-0-9
Lecture: MWF10 (54-100) +final
______
Probability spaces, random variables, distribution functions. Binomial, geometric, hypergeometric, Poisson distributions. Uniform, exponential, normal, gamma and beta distributions. Conditional probability, Bayes theorem, joint distributions. Chebyshev inequality, law of large numbers, and central limit theorem. Credit cannot also be received for 6.041A or 6.041B.
Fall:E. Mossel
Spring:S. Sheffield
Textbooks (Fall 2016)

18.615 Introduction to Stochastic Processes
______

Graduate (Spring)
Prereq: 18.600 or 6.041B
Units: 3-0-9
______
Basics of stochastic processes. Markov chains, Poisson processes, random walks, birth and death processes, Brownian motion.
A. Bufetov

18.642 Topics in Mathematics with Applications in Finance
______

Undergrad (Fall)
Prereq: 18.03; 18.06; 18.05 or 18.600
Units: 3-0-9
Lecture: TR2.30-4 (4-163)
______
Introduction to mathematical concepts and techniques used in finance. Lectures focusing on linear algebra, probability, statistics, stochastic processes, and numerical methods are interspersed with lectures by financial sector professionals illustrating the corresponding application in the industry. Prior knowledge of economics or finance helpful but not required.
P. Kempthorne, V. Strela, J. Xia
Textbooks (Fall 2016)

18.650 Statistics for Applications
______

Undergrad (Fall, Spring)
(Subject meets with18.6501)
Prereq: 18.600 or 6.041B
Units: 3-0-9
Lecture: TR1-2.30 (2-190) +final
______
A broad treatment of statistics, concentrating on specific statistical techniques used in science and industry. Topics: hypothesis testing and estimation. Confidence intervals, chi-square tests, nonparametric statistics, analysis of variance, regression, correlation, decision theory, and Bayesian statistics.
Fall:P. Rigollet
Spring:P. Kempthorne
No required or recommended textbooks

18.6501 Statistics for Applications
______

Graduate (Fall, Spring)
(Subject meets with18.650)
Prereq: 18.600 or 6.041B
Units: 3-0-9
Lecture: TR1-2.30 (2-190) +final
______
A broad treatment of statistics, concentrating on specific statistical techniques used in science and industry. Topics: hypothesis testing and estimation. Confidence intervals, chi-square tests, nonparametric statistics, analysis of variance, regression, correlation, decision theory, and Bayesian statistics. Students in Course 18 must register for the undergraduate version, 18.650.
Fall:P. Rigollet
Spring:P. Kempthorne
No required or recommended textbooks

18.655 Mathematical Statistics
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Decision theory, estimation, confidence intervals, hypothesis testing. Introduces large sample theory. Asymptotic efficiency of estimates. Exponential families. Sequential analysis.
P. Kempthorne

18.657 Topics in Statistics
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
Topics vary from term to term.
P. Rigollet

For additional related subjects in Statistics, see:

Civil and Environmental Engineering: 1.151, 1.155,1.202J, 1.203J, 1.205J

Electrical Engineering and Computer Science: 6.041,6.231, 6.245, 6.262, 6.431, 6.432, and 6.435

Management: 15.034, 15.061, 15.065, 15.070, 15.075, 15.076, 15.098, and 15.306

Mathematics: 18.05, 18.175, 18.176, 18.177, 18.600, 18.615, 18.642, 18.650, 18.655, and 18.657

See also: 2.061, 2.830, 5.70, 5.72, 7.02, 8.044, 8.08,10.816, 11.220, 11.221, 16.322, 17.872, 17.874, 22.38, HST.191, and MAS.622J.

Algebra and Number Theory

18.700 Linear Algebra
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: Calculus II (GIR)
Units: 3-0-9
Credit cannot also be received for18.06
URL: http://math.mit.edu/classes/18.700
Lecture: MWF1 (2-105) +final
______
Vector spaces, systems of linear equations, bases, linear independence, matrices, determinants, eigenvalues, inner products, quadratic forms, and canonical forms of matrices. More emphasis on theory and proofs than in 18.06.
C. Xu
Textbooks (Fall 2016)

18.701 Algebra I
______

Undergrad (Fall)
Prereq: 18.100A, 18.100B, 18.100P, 18.100Q, or permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.701
Lecture: MWF11 (2-190)
______
M. Artin
Textbooks (Fall 2016)

18.702 Algebra II
______

Undergrad (Spring)
Prereq: 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.702
______
More extensive and theoretical than the 18.700-18.703 sequence. Experience with proofs necessary. First term: group theory, geometry, and linear algebra. Second term: group representations, rings, ideals, fields, polynomial rings, modules, factorization, integers in quadratic number fields, field extensions, Galois theory.
M. Artin

18.703 Modern Algebra
______

Undergrad (Spring)
Prereq: Calculus II (GIR)
Units: 3-0-9
URL: http://math.mit.edu/classes/18.703/
______
Focuses on traditional algebra topics that have found greatest application in science and engineering as well as in mathematics: group theory, emphasizing finite groups; ring theory, including ideals and unique factorization in polynomial and Euclidean rings; field theory, including properties and applications of finite fields. 18.700 and 18.703 together form a standard algebra sequence.
P. I. Etingof

18.704 Seminar in Algebra
______

Undergrad (Spring)
Prereq: 18.701; or 18.06, 18.703; or 18.700, 18.703
Units: 3-0-9
URL: http://math.mit.edu/classes/18.704
______
Topics vary from year to year. Students present and discuss the subject matter. Instruction and practice in written and oral communication provided. Some experience with proofs required. Enrollment limited.
V. G. Kac

18.705 Commutative Algebra
______

Graduate (Fall)
Prereq: 18.702
Units: 3-0-9
URL: http://math.mit.edu/classes/18.705
Lecture: TR11-12.30 (2-132)
______
Exactness, direct limits, tensor products, Cayley-Hamilton theorem, integral dependence, localization, Cohen-Seidenberg theory, Noether normalization, Nullstellensatz, chain conditions, primary decomposition, length, Hilbert functions, dimension theory, completion, Dedekind domains.
A. Negut
Textbooks (Fall 2016)

18.706 Noncommutative Algebra
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 18.705
Units: 3-0-9
URL: http://math.mit.edu/classes/18.706/
______
Topics may include representations of quivers, Wedderburn theory, Morita equivalence, localization and Goldie's theorem, central simple algebras and the Brauer group, maximal orders, representations, polynomial identity rings, invariant theory growth of algebras, Gelfand-Kirillov dimension.
G. Lusztig

18.708 Topics in Algebra
______

Not offered academic year 2017-2018Graduate (Spring) Can be repeated for credit
Prereq: 18.705
Units: 3-0-9
______
Topics vary from year to year.
Information: P. I. Etingof

18.715 Introduction to Representation Theory
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 18.702 or 18.703
Units: 3-0-9
Lecture: TR9.30-11 (4-163)
______
Algebras, representations, Schur's lemma. Representations of SL(2). Representations of finite groups, Maschke's theorem, characters, applications. Induced representations, Burnside's theorem, Mackey formula, Frobenius reciprocity. Representations of quivers.
B. Poonen
No required or recommended textbooks

18.721 Introduction to Algebraic Geometry
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 18.702, 18.901
Units: 3-0-9
URL: http://math.mit.edu/classes/18.721
______
Presents basic examples of complex algebraic varieties, affine and projective algebraic geometry, sheaves, cohomology.
M. Artin

18.725 Algebraic Geometry I
______

Graduate (Fall)
Prereq: None.Coreq: 18.705
Units: 3-0-9
URL: http://math.mit.edu/classes/18.725
Lecture: TR12.30-2 (2-135)
______
Introduces the basic notions and techniques of modern algebraic geometry. Covers fundamental notions and results about algebraic varieties over an algebraically closed field; relations between complex algebraic varieties and complex analytic varieties; and examples with emphasis on algebraic curves and surfaces. Introduction to the language of schemes and properties of morphisms. Knowledge of elementary algebraic topology, elementary differential geometry recommended, but not required.
A. Pixton
No required or recommended textbooks

18.726 Algebraic Geometry II
______

Graduate (Spring)
Prereq: 18.725
Units: 3-0-9
URL: http://math.mit.edu/classes/18.726
______
Continuation of the introduction to algebraic geometry given in 18.725. More advanced properties of the varieties and morphisms of schemes, as well as sheaf cohomology.
D. Maulik

18.727 Topics in Algebraic Geometry
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: 18.725
Units: 3-0-9
URL: http://math.mit.edu/classes/18.727
______
Topics vary from year to year.
Information: D. A. Vogan

18.737 Algebraic Groups
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 18.705
Units: 3-0-9
URL: http://math.mit.edu/classes/18.737
Lecture: MW2-3.30 (2-142)
______
Structure of linear algebraic groups over an algebraically closed field, with emphasis on reductive groups. Representations of groups over a finite field using methods from etale cohomology. Some results from algebraic geometry are stated without proof.
G. Lusztig
No required or recommended textbooks

18.745 Introduction to Lie Algebras
______

Graduate (Fall)
Prereq: 18.701 or 18.703
Units: 3-0-9
URL: http://math.mit.edu/classes/18.745
Lecture: TR2.30-4 (2-139)
______
Topics may include structure of finite-dimensional Lie algebras; theorems of Engel and Lie; Cartan subalgebras and regular elements; trace form and Cartan's criterion; Chevalley's conjugacy theorem; classification and construction of semisimple Lie algebras; Weyl group; universal enveloping algebra and the Casimir operator; Weyl's complete reducibility theorem, Levi and Maltsev theorems; Verma modules; classification of irreducible finite-dimensional representations of semisimple Lie algebras; Weyl's character and dimension formulas.
V. G. Kac
No required or recommended textbooks

18.747 Infinite-dimensional Lie Algebras
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.745
Units: 3-0-9
______
Topics vary from year to year.
P. I. Etingof

18.748 Topics in Lie Theory
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
______
Topics vary from year to year.
P. I. Etingof

18.755 Introduction to Lie Groups
______

Graduate (Fall)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.700 or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.755
Lecture: MWF10 (2-135)
______
A general introduction to manifolds and Lie groups. The role of Lie groups in mathematics and physics. Exponential mapping. Correspondence with Lie algebras. Homogeneous spaces and transformation groups. Adjoint representation. Covering groups. Automorphism groups. Invariant differential forms and cohomology of Lie groups and homogeneous spaces. 18.101 recommended but not required.
S. A. Altug
No required or recommended textbooks

18.757 Representations of Lie Groups
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: 18.745 or 18.755
Units: 3-0-9
URL: http://www-math.mit.edu/~laurajoy/rep.html
______
Covers representations of locally compact groups, with emphasis on compact groups and abelian groups. Includes Peter-Weyl theorem and Cartan-Weyl highest weight theory for compact Lie groups.
L. Rider

18.781 Theory of Numbers
______

Undergrad (Spring)
Prereq: None
Units: 3-0-9
URL: http://math.mit.edu/classes/18.781
______
An elementary introduction to number theory with no algebraic prerequisites. Primes, congruences, quadratic reciprocity, diophantine equations, irrational numbers, continued fractions, partitions.
Information: D. A. Vogan

18.782 Introduction to Arithmetic Geometry
______

Not offered academic year 2016-2017Undergrad (Fall)
Prereq: 18.702
Units: 3-0-9
URL: http://math.mit.edu/classes/18.782
______
Exposes students to arithmetic geometry, motivated by the problem of finding rational points on curves. Includes an introduction to p-adic numbers and some fundamental results from number theory and algebraic geometry, such as the Hasse-Minkowski theorem and the Riemann-Roch theorem for curves. Additional topics may include Mordell's theorem, the Weil conjectures, and Jacobian varieties.
A. Sutherland

18.783 Elliptic Curves
______

Not offered academic year 2017-2018Undergrad (Spring)
(Subject meets with18.7831)
Prereq: None.Coreq: 18.702, 18.703, or permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.783
______
Computationally focused introduction to elliptic curves, with applications to number theory and cryptography. Topics include point-counting, isogenies, pairings, and the theory of complex multiplication, with applications to integer factorization, primality proving, and elliptic curve cryptography. Includes a brief introduction to modular curves and the proof of Fermat's Last Theorem.
A. Sutherland

18.7831 Elliptic Curves
______

Not offered academic year 2017-2018Graduate (Spring)
(Subject meets with18.783)
Prereq: None.Coreq: 18.702, 18.703, or permission of instructor
Units: 3-0-9
______
Computationally focused introduction to elliptic curves, with applications to number theory and cryptography. Topics include point-counting, isogenies, pairings, and the theory of complex multiplication, with applications to integer factorization, primality proving, and elliptic curve cryptography. Includes a brief introduction to modular curves and the proof of Fermat's Last Theorem. Students in Course 18 must register for the undergraduate version, 18.783.
A. Sutherland

18.784 Seminar in Number Theory
______

Undergrad (Fall)
Prereq: 18.06; 18.100A, 18.100B, 18.100P, or 18.100Q
Units: 3-0-9
URL: http://web.mit.edu/abhinavk/www/18.784/index.html
Lecture: MWF11 (2-151)
______
Topics vary from year to year. Students present and discuss the subject matter. Instruction and practice in written and oral communication provided. Enrollment limited.
D. Maulik
Textbooks (Fall 2016)

18.785 Number Theory I
______

Graduate (Fall)
Prereq: None.Coreq: 18.705
Units: 3-0-9
URL: http://math.mit.edu/classes/18.785
Lecture: TR2.30-4 (2-143)
______
Dedekind domains, unique factorization of ideals, splitting of primes. Lattice methods, finiteness of the class group, Dirichlet's unit theorem. Local fields, ramification, discriminants. Zeta and L-functions, analytic class number formula. Adeles and ideles. Statements of class field theory and the Chebotarev density theorem.
A. Sutherland
No required or recommended textbooks

18.786 Number Theory II
______

Graduate (Spring)
Prereq: 18.785
Units: 3-0-9
URL: http://math.mit.edu/classes/18.786
______
Continuation of 18.785. More advanced topics in number theory, such as Galois cohomology, proofs of class field theory, modular forms and automorphic forms, Galois representations, or quadratic forms.
C. C. Tsai

18.787 Topics in Number Theory
______

Not offered academic year 2016-2017Graduate (Fall) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.787/
______
Topics vary from year to year.
B. Poonen

Mathematics Laboratory

18.821 Project Laboratory in Mathematics
______

Undergrad (Fall, Spring) Institute Lab
Prereq: Two mathematics subjects numbered 18.100 or above
Units: 3-6-3
URL: http://math.mit.edu/classes/18.821/
Lecture: MW1,F1-3 (2-147)
______
Guided research in mathematics, employing the scientific method. Students confront puzzling and complex mathematical situations, through the acquisition of data by computer, pencil and paper, or physical experimentation, and attempt to explain them mathematically. Students choose three projects from a large collection of options. Each project results in a laboratory report subject to revision; oral presentation on one or two projects. Projects drawn from many areas, including dynamical systems, number theory, algebra, fluid mechanics, asymptotic analysis, knot theory, and probability. Enrollment limited.
Fall:D. A. Vogan
Spring:R. Bezrukavnikov
No required or recommended textbooks

Topology and Geometry

18.901 Introduction to Topology
______

Undergrad (Fall, Spring)
(Subject meets with18.9011)
Prereq: 18.100A, 18.100B, 18.100P, 18.100Q, or permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.901/
Lecture: TR9.30-11 (4-261)
______
Introduces topology, covering topics fundamental to modern analysis and geometry. Topological spaces and continuous functions, connectedness, compactness, separation axioms, and selected further topics such as function spaces, embedding theorems, dimension theory, or covering spaces and the fundamental group.
Fall:M. Hoyois
Spring:T. Walpuski
Textbooks (Fall 2016)

18.9011 Introduction to Topology
______

Graduate (Fall, Spring)
(Subject meets with18.901)
Prereq: 18.100A, 18.100B, 18.100P, 18.100Q, or permission of instructor
Units: 3-0-9
Lecture: TR9.30-11 (4-261)
______
Introduces topology, covering topics fundamental to modern analysis and geometry. Topological spaces and continuous functions, connectedness, compactness, separation axioms, and selected further topics such as function spaces, embedding theorems, dimension theory, or covering spaces and the fundamental group. Students in Course 18 must register for the undergraduate version, 18.901.
Fall:M. Hoyois
Spring:T. Walpuski
Textbooks (Fall 2016)

18.904 Seminar in Topology
______

Undergrad (Spring)
Prereq: 18.901
Units: 3-0-9
URL: http://math.mit.edu/classes/18.904/
______
Topics vary from year to year and include the fundamental group and covering spaces. Time permitting, also covers the relationship between these objects and the theory of knots. Students present and discuss the subject matter. Instruction and practice in written and oral communication provided. Enrollment limited.
G. Tabuada

18.905 Algebraic Topology I
______

Graduate (Fall)
Prereq: 18.701 or 18.703; 18.901
Units: 3-0-9
URL: http://math.mit.edu/classes/18.905/
Lecture: MWF11 (2-147) +final
______
Singular homology, CW complexes, universal coefficient and Künneth theorems, cohomology, cup products, Poincaré duality.
H. R. Miller
No required or recommended textbooks

18.906 Algebraic Topology II
______

Graduate (Spring)
Prereq: 18.905
Units: 3-0-9
URL: http://math.mit.edu/classes/18.906/
______
Continues the introduction to Algebraic Topology from 18.905. Topics include basic homotopy theory, spectral sequences, characteristic classes, and cohomology operations.
H. R. Miller

18.917 Topics in Algebraic Topology
______

Graduate (Spring) Can be repeated for credit
Prereq: 18.906
Units: 3-0-9
URL: http://math.mit.edu/classes/18.917/
______
Content varies from year to year. Introduces new and significant developments in algebraic topology with the focus on homotopy theory and related areas.
C. Barwick

18.919 Graduate Topology Seminar
______

Graduate (Fall)
Prereq: 18.906
Units: 3-0-9
Lecture: MW9.30-11 (2-151)
______
Study and discussion of important original papers in the various parts of algebraic topology. Open to all students who have taken 18.906 or the equivalent, not only prospective topologists.
G. Tabuada
No required or recommended textbooks

18.937 Topics in Geometric Topology
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.937
______
Content varies from year to year. Introduces new and significant developments in geometric topology.
E. Murphy

18.950 Differential Geometry
______

Undergrad (Fall)
(Subject meets with18.9501)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.950/2016fa/index.html
Lecture: MWF1 (2-131) +final
______
Introduction to differential geometry, centered on notions of curvature. Starts with curves in the plane, and proceeds to higher dimensional submanifolds. Computations in coordinate charts: first and second fundamental form, Christoffel symbols. Discusses the distinction between extrinsic and intrinsic aspects, in particular Gauss' theorema egregium. The Gauss-Bonnet theorem. Geodesics. Examples such as hyperbolic space.
H. Macbeth
No required or recommended textbooks

18.9501 Differential Geometry
______

Graduate (Fall)
(Subject meets with18.950)
Prereq: 18.100A, 18.100B, 18.100P, or 18.100Q; 18.06, 18.700, or 18.701
Units: 3-0-9
Lecture: MWF1 (2-131) +final
______
Introduction to differential geometry, centered on notions of curvature. Starts with curves in the plane, and proceeds to higher dimensional submanifolds. Computations in coordinate charts: first and second fundamental form, Christoffel symbols. Discusses the distinction between extrinsic and intrinsic aspects, in particular Gauss' theorema egregium. The Gauss-Bonnet theorem. Geodesics. Examples such as hyperbolic space. Students in Course 18 must register for the undergraduate version, 18.950.
H. Macbeth
No textbook information available

18.952 Theory of Differential Forms
______

Not offered academic year 2016-2017Undergrad (Spring)
Prereq: 18.101; 18.700 or 18.701
Units: 3-0-9
URL: http://math.mit.edu/classes/18.952/
______
Multilinear algebra: tensors and exterior forms. Differential forms on Rn: exterior differentiation, the pull-back operation and the Poincaré lemma. Applications to physics: Maxwell's equations from the differential form perspective. Integration of forms on open sets of Rn. The change of variables formula revisited. The degree of a differentiable mapping. Differential forms on manifolds and De Rham theory. Integration of forms on manifolds and Stokes' theorem. The push-forward operation for forms. Thom forms and intersection theory. Applications to differential topology.
V. W. Guillemin

18.965 Geometry of Manifolds I
______

Graduate (Fall)
Prereq: 18.101, 18.950 or 18.952
Units: 3-0-9
URL: http://math.mit.edu/classes/18.965
Lecture: TR9.30-11 (2-135)
______
No required or recommended textbooks

18.966 Geometry of Manifolds II
______

Graduate (Spring)
Prereq: 18.965
Units: 3-0-9
URL: http://math.mit.edu/classes/18.966
______
Differential forms, introduction to Lie groups, the DeRham theorem, Riemannian manifolds, curvature, the Hodge theory. 18.966 is a continuation of 18.965 and focuses more deeply on various aspects of the geometry of manifolds. Contents vary from year to year, and can range from Riemannian geometry (curvature, holonomy) to symplectic geometry, complex geometry and Hodge-Kahler theory, or smooth manifold topology. Prior exposure to calculus on manifolds, as in 18.952, is recommended.
Fall:T. Walpuski
Spring:W. Minicozzi

18.968 Topics in Geometry
______

Not offered academic year 2017-2018Graduate (Fall) Can be repeated for credit
Prereq: 18.965
Units: 3-0-9
Lecture: TR9.30-11 (2-151)
______
Content varies from year to year.
T. Colding
No textbook information available

18.979 Graduate Geometry Seminar
______

Not offered academic year 2016-2017Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 3-0-9
URL: http://math.mit.edu/classes/18.979
______
Content varies from year to year. Study of classical papers in geometry and in applications of analysis to geometry and topology.
T. Mrowka

18.994 Seminar in Geometry
______

Undergrad (Fall)
Prereq: 18.101, 18.102, 18.103, or 18.112
Units: 3-0-9
Lecture: TR1-2.30 (2-151)
______
Students present and discuss subject matter taken from current journals or books. Topics vary from year to year. Instruction and practice in written and oral communication provided. Enrollment limited.
R. Hynd
Textbooks (Fall 2016)

18.999 Research in Mathematics
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Opportunity for study of graduate-level topics in mathematics under the supervision of a member of the department. For graduate students desiring advanced work not provided in regular subjects.
Information: W. Minicozzi
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

18.UR Undergraduate Research
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Undergraduate research opportunities in mathematics. Permission required in advance to register for this subject. For further information, consult the departmental coordinator.
Information: J. W. Bush
Textbooks arranged individually

18.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of a Ph.D. thesis; to be arranged by the student and an appropriate MIT faculty member.
Information: W. Minicozzi
Textbooks arranged individually

18.S096 Special Subject in Mathematics
______

Undergrad (IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
______

18.S097 Special Subject in Mathematics
______

Undergrad (IAP, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
______
Opportunity for group study of subjects in mathematics not otherwise included in the curriculum. Offerings are initiated by members of the Mathematics faculty on an ad hoc basis, subject to departmental approval. 18.S097 is graded P/D/F.
Information: J. W. Bush

18.S995-18.S998 Special Subject in Mathematics
______

Graduate (Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
18.S996: URL: http://math.mit.edu/classes/18.S996/
18.S995: Lecture: TR2.30-4 (2-136)
Subject Cancelled 18.S998 Cancelled
______
Opportunity for group study of advanced subjects in mathematics not otherwise included in the curriculum. Offerings are initiated by members of the Mathematics faculty on an ad hoc basis, subject to departmental approval.
Information: J. W. Bush
18.S995: No required or recommended textbooks


left arrow|18.01-18.499|18.50-18.THG|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 20: Biological Engineering
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Course 20: Biological Engineering
Fall 2016


20.002 Metakaryotic Biology and Epidemiology
______

Undergrad (Fall)
(Subject meets with20.A02)
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: F3-5 (56-711)
______
Introduces non-eukaryotic metakaryotic cells that serve as the stem cells of human fetal/juvenile growth and development. Considers their peculiar modes of genome organization in chromosomal rings, replication via dsRNA/DNA intermediates and amitotic segregation. Explores the hypothesis that high mutation rates in these cells lead to cancers and atherosclerotic plaques and account for the increasing death rates observed with human age.
W. Thilly
No textbook information available

20.020 Introduction to Biological Engineering Design Using Synthetic Biology
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with20.385)
Prereq: None
Units: 3-3-3
______
Project-based introduction to the engineering of synthetic biological systems. Throughout the term, students develop projects that are responsive to real-world problems of their choosing, and whose solutions depend on biological technologies. Lectures, discussions, and studio exercises will introduce components and control of prokaryotic and eukaryotic behavior; DNA synthesis, standards, and abstraction in biological engineering; and issues of human practice, including biological safety, security, ethics, and ownership, sharing, and innovation. Preference to freshmen.
N. Kuldell

20.102 Stem Cells in Organogenesis, Carcinogenesis, and Atherogenesis
______

Undergrad (Fall)
(Subject meets with20.215)
Prereq: Calculus II (GIR), Biology (GIR), Chemistry (GIR)
Units: 3-0-9
Lecture: TR1-2.30 (16-220)
______
Study of the amitotic metakaryotic stem cells in fetal/juvenile organogenesis and wound healing. Explores their roles as stem cells in clonal diseases such as cancers and atherosclerosis. Application of a hypermutable/mutator stem cell model to the analysis of age-specific mortality from clonal diseases. Students taking 20.215 do additional research and computer modeling.
E. V. Gostjeva, W. G. Thilly
No textbook information available

20.104[J] Environmental Cancer Risks, Prevention, and Therapy
______

Undergrad (Spring)
(Same subject as1.081[J])
Prereq: Calculus II (GIR), Biology (GIR), Chemistry (GIR)
Units: 3-0-9
______
Analysis of the history of cancer and vascular disease mortality rates in predominantly European- and African-American US cohorts, 1895-2010, to discover specific historical shifts. Shifts identified are explored in terms of contemporaneously changing environmental risk factors: air-, food- and water-borne chemicals; subclinical infections; diet and lifestyles. Role of occupational data identifying general risk factors. Considers the hypotheses that environmental factors affect metakaryotic stem cell mutation rates in fetuses and juveniles and/or the growth rates of preneoplastic stem cells in adults. Interaction of environmental and inherited risks. Introduces the use of metakaryocidal drugs to treat cancer in clinical trials.
W. Thilly, R. McCunney

20.106[J] Systems Microbiology
______

Undergrad (Fall)
(Same subject as1.084[J])
Prereq: Chemistry (GIR), Biology (GIR)
Units: 3-0-9
Lecture: TR2.30-4 (56-614)
______
Introductory microbiology from a systems perspective - considers microbial diversity and the integration of data from a molecular, cellular, organismal, and ecological context to understand the interaction of microbial organisms with their environment. Special emphasis on specific viral, bacterial, and eukaryotic microorganisms and their interaction with animal hosts with focus on contemporary problems in areas such as vaccination, emerging disease, antimicrobial drug resistance, and toxicology.
E. Alm, J. Niles
No textbook information available

20.109 Laboratory Fundamentals in Biological Engineering
______

Undergrad (Fall, Spring) Institute Lab
Prereq: Biology (GIR), Chemistry (GIR), 6.0002, 18.03, 20.110
Units: 2-8-5
Lecture: TR11 (16-220) Lab: TR1-5 (56-322) or WF1-5 (56-322)
______
Introduces experimental biochemical and molecular techniques from a quantitative engineering perspective. Experimental design, data analysis, and scientific communication form the underpinnings of this subject. Examples of discovery-based experimental modules include DNA engineering in which students design, construct, and use genetic material; parts engineering, which emphasizes protein design and quantitative assessment of protein performance; systems engineering, in which students consider genome-wide consequences of genetic perturbations; and biomaterials engineering, in which students use biologically-encoded devices to design and build materials. Students complete some laboratory time online in advance of each class. Enrollment limited; priority to Course 20 majors.
Fall:A. Belcher, B. Engelward, M. Jonas, N. Lyell, L. McClain
Spring:A. Belcher, L. Samson, M. Jonas, N. Lyell, L. McClain
No textbook information available

20.110[J] Thermodynamics of Biomolecular Systems
______

Undergrad (Fall, Spring) Rest Elec in Sci & Tech
(Same subject as2.772[J])
Prereq: Calculus II (GIR), Chemistry (GIR), Physics I (GIR)
Units: 5-0-7
Lecture: MWF10 (4-270) Recitation: TR10 (26-168) or TR1 (66-154) or TR4 (56-169) +final
______
Equilibrium properties of macroscopic and microscopic systems. Basic thermodynamics: state of a system, state variables. Work, heat, first law of thermodynamics, thermochemistry. Second and third law of thermodynamics: entropy and its statistical basis, Gibbs function. Chemical equilibrium of reactions in gas and solution phase. Macromolecular structure and interactions in solution. Driving forces for molecular self-assembly. Binding cooperativity, solvation, titration of macromolecules.
Fall:M. Birnbaum C. Voigt
Spring:E. Alm, C. Voigt
No textbook information available

20.129[J] Biological Circuit Engineering Laboratory
______

Undergrad (Spring) Institute Lab
(Same subject as6.129[J])
Prereq: Biology (GIR), Calculus II (GIR)
Units: 2-8-2
______
Students assemble individual genes and regulatory elements into larger-scale circuits; they experimentally characterize these circuits in yeast cells using quantitative techniques, including flow cytometry, and model their results computationally. Emphasizes concepts and techniques to perform independent experimental and computational synthetic biology research. Discusses current literature and ongoing research in the field of synthetic biology. Instruction and practice in oral and written communication provided. Enrollment limited.
T. Lu, R. Weiss

20.200 Biological Engineering Seminar
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units: 1-0-2 [P/D/F]
Lecture: F12 (32-155)
______
Weekly one-hour seminars covering graduate student research and presentations by invited speakers. Limited to BE graduate students.
B. Engelward
No textbook information available

20.201 Fundamentals of Drug Development
______

Graduate (Fall)
Prereq: Permission of instructor
Units: 4-0-8
Lecture: MW1.30-3 (56-614) Recitation: F1.30 (56-614)
______
Addresses the scientific basis for the development of new drugs. First half of term begins with an overview of the drug discovery process, followed by fundamental principles of pharmacokinetics, pharmacodynamics, metabolism, and the mechanisms by which drugs cause therapeutic and toxic responses. Second half applies principles to case studies and literature discussions of current problems with specific drugs, drug classes, and therapeutic targets.
P. C. Dedon, M. A. Murcko, R. Sasisekharan
No textbook information available

20.202 In vivo Models: Principles and Practices
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 1-1-4
______
Selected aspects of anatomy, histology, immuno-cytochemistry, in situ hybridization, physiology, and cell biology of mammalian organisms and their pathogens. Subject material integrated with principles of toxicology, in vivo genetic engineering, and molecular biology. A lab/demonstration period each week involves experiments in anatomy (in vivo), physiology, and microscopy to augment the lectures. Offered first half of spring term.
J. G. Fox, B. Marini, M. Whary

20.203[J] Neurotechnology in Action
______

Graduate (Fall)
(Same subject as9.123[J])
Prereq: Permission of instructor
Units: 3-6-3
Lecture: TR2.30-4 (46-4062)
______
Offers a fast-paced introduction to numerous laboratory methods at the forefront of modern neurobiology. Comprises a sequence of modules focusing on neurotechnologies that are developed and used by MIT research groups. Each module consists of a background lecture and 1-2 days of firsthand laboratory experience. Topics typically include optical imaging, optogenetics, high throughput neurobiology, MRI/fMRI, advanced electrophysiology, viral and genetic tools, and connectomics.
A. Jasanoff, E. Boyden, M. Jonas
No required or recommended textbooks

20.205[J] Principles and Applications of Genetic Engineering for Biotechnology and Neuroscience
______

Undergrad (Spring)
(Same subject as9.26[J])
Prereq: 7.28, 7.32, or 20.020; 9.01 or 9.09
Units: 3-0-9
______
Covers principles underlying current and future genetic engineering approaches, ranging from single cellular organisms to whole animals. Focuses on development and invention of technologies for engineering biological systems at the genomic level, and applications of engineered biological systems for medical and biotechnological needs, with particular emphasis on genetic manipulation of the nervous system. Design projects by students.
F. Zhang

20.207 Biotechnologies in Infectious Disease
______

Graduate (Spring)
Prereq: 7.06, permission of instructor
Units: 3-0-9
______
In-depth exploration of current and emerging technologies used in the surveillance, diagnosis, understanding, treatment and prevention of infectious diseases, drawing on basic science and engineering principles. Develops practical problem-solving skills relevant to infectious disease issues on a global scale. In partnership with students in Southeast Asia via edX, MIT students participate in global collaborations focusing on case studies of distinct pathogens. Together, both groups of students then apply these principles longitudinally in a team-based project on technology applications in infectious disease that culminates in a presentation at the end of the term.
P. C. Dedon, J.C. Niles, R. Sasisekharan

20.213 DNA Damage and Genomic Instability
______

Graduate (Spring)
Prereq: 5.07, 7.05, permission of instructor
Units: 4-0-8
______
Focuses on biochemistry and molecular mechanisms of DNA replication and DNA repair. Analyzes chemistry of DNA damaging events, and analyzes mutagenic and toxic consequences of modifications to DNA structure. Also presents the contrasting perspective that normal DNA processing leads to mutations. Moves from analysis and discussion of key DNA repair pathways to connections between DNA repair and human diseases. Discusses in-depth the chemistry and biochemistry of DNA metabolism. Includes current literature related to the molecular mechanisms of radiation and chemotherapy.
B. P. Engelward, L. Samson

20.215 Macroepidemiology, Population Genetics, and Stem Cell Biology of Human Clonal Diseases
______

Graduate (Fall)
(Subject meets with20.102)
Prereq: Calculus II (GIR), 1.00
Units: 3-0-15
Lecture: TR1-2.30 (16-220)
______
Studies the logic and technology needed to discover genetic and environmental risks for common human cancers and vascular diseases. Includes an introduction to metakaryotic stem cell biology. Analyzes large, organized historical public health databases using quantitative cascade computer models that include population stratification of stem cell mutation rates in fetal/juvenile tissues and growth rates in preneoplastic colonies and atherosclerotic plaques. Means to test hypotheses (CAST) that certain genes carry mutations conferring risk for common cancers via genetic analyses in large human cohorts.
W. G. Thilly
No textbook information available

20.219 Selected Topics in Biological Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Detailed discussion of selected topics of current interest. Classwork in various areas not covered by regular subjects.
Staff
No textbook information available

20.260 Analysis and Presentation of Complex Biological Data
______

Undergrad (IAP)
Prereq: Permission of instructor
Units: 2-0-2 [P/D/F]
______
Illustrates best practices in the statistical analysis of complex biological datasets and the graphical representation of such analyses. Covers fundamental concepts in probability and statistical theory as well as principles of information design. Provides mathematical concepts and tools that enable students to make sound judgments about the application of statistical methods and to present statistical results in clear and compelling visual formats. Assignments focus on key concepts and their application to practical examples. Assumes basic knowledge of calculus and programming in MATLAB or R.
P. Blainey

20.300 Advanced Workshop in Biological Engineering Communication: Professors Share Their Practices
______

Undergrad (IAP)
Prereq: Permission of instructor
Units: 3-0-0 [P/D/F]
______
Working scientists and engineers discuss best practices for written, visual, and oral communication in the classroom, the lab, and the workplace. In a series of lectures, successful academics and industry professionals share how they prepare papers, talks, and graphics. Recitations allow deeper exploration of the lecture topics. With faculty guidance, students develop their own projects during workshops. Emphasizes systematic approaches and transferable skills such as effective drafting and revision. Topics include creating compelling visuals to represent data and concepts; formal/informal writing, from research papers to cover letters; and developing memorable talks and presentations. Examples drawn from biological engineering research. Enrollment limited; preference to Course 20 majors.
E. Alm, J. Goldstein, A. Stachowiak

20.305[J] Principles of Synthetic Biology
______

Undergrad (Fall)
(Same subject as6.580[J])
(Subject meets with6.589[J],20.405[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (9-057) +final
______
Introduces the basics of synthetic biology, including quantitative cellular network characterization and modeling. Considers the discovery and genetic factoring of useful cellular activities into reusable functions for design. Emphasizes the principles of biomolecular system design and diagnosis of designed systems. Illustrates cutting-edge applications in synthetic biology and enhances skills in analysis and design of synthetic biological applications. Students taking graduate version complete additional assignments.
R. Weiss
No textbook information available

20.309[J] Instrumentation and Measurement for Biological Systems
______

Undergrad (Fall, Spring)
(Same subject as2.673[J])
(Subject meets with20.409)
Prereq: Biology (GIR), Physics II (GIR), 6.0002, 18.03; or permission of instructor
Units: 3-6-3
Lecture: TR12 (32-155) Recitation: F12 (56-114)
______
Sensing and measurement aimed at quantitative molecular/cell/tissue analysis in terms of genetic, biochemical, and biophysical properties. Methods include light and fluorescence microscopies, and electro-mechanical probes (atomic force microscopy, optical traps, MEMS devices). Application of statistics, probability, signal and noise analysis, and Fourier techniques to experimental data. Enrollment limited; preference to Course 20 undergraduates.
Fall:P. Blainey, S. Manalis, E. Frank, S. Wasserman, J. Bagnall
Spring:E. Boyden, P. So, S. Wasserman, J. Bagnall, E. Frank
No textbook information available

20.310[J] Molecular, Cellular, and Tissue Biomechanics
______

Undergrad (Spring)
(Same subject as2.797[J],3.053[J],6.024[J])
Prereq: 2.370 or 2.772J; 18.03 or 3.016; Biology (GIR)
Units: 4-0-8
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, A. J. Grodzinsky, K. Van Vliet

20.315 Physical Biology
(New)
______

Undergrad (Spring)
(Subject meets with20.415)
Prereq: 20.110, 5.60, or permission of instructor
Units: 3-0-9
______
Focuses on current major research topics in quantitative, physical biology. Covers synthetic structural biology, synthetic cell biology, microbial systems biology and evolution, cellular decision making, neuronal circuits, and development and morphogenesis. Emphasizes current motivation and historical background, state-of-the-art measurement methodologies and techniques, and quantitative physical modeling frameworks. Experimental techniques include structural biology, next-generation sequencing, fluorescence imaging and spectroscopy, and quantitative biochemistry. Modeling approaches include stochastic rate equations, statistical thermodynamics, and statistical inference. Students taking graduate version complete additional assignments.
M. Bathe, P. Blainey

20.320 Analysis of Biomolecular and Cellular Systems
______

Undergrad (Fall)
Prereq: 20.110, 18.03, 6.0002;Coreq: 5.07 or 7.05
Units: 4-0-8
Lecture: TR9.30-11 (32-141) Recitation: M3 (56-114) or F10 (4-153)
______
Analysis of molecular and cellular processes across a hierarchy of scales, including genetic, molecular, cellular, and cell population levels. Topics include gene sequence analysis, molecular modeling, metabolic and gene regulation networks, signal transduction pathways and cell populations in tissues. Emphasis on experimental methods, quantitative analysis, and computational modeling.
F. White, K. D. Wittrup
No textbook information available

20.330[J] Fields, Forces and Flows in Biological Systems
______

Undergrad (Spring)
(Same subject as2.793[J],6.023[J])
Prereq: Physics II (GIR); 2.005, 6.021, or permission of instructor,Coreq: 20.309
Units: 4-0-8
______
Introduction to electric fields, fluid flows, transport phenomena and their application to biological systems. Flux and continuity laws, Maxwell's equations, electro-quasistatics, electro-chemical-mechanical driving forces, conservation of mass and momentum, Navier-Stokes flows, and electrokinetics. Applications include biomolecular transport in tissues, electrophoresis, and microfluidics.
J. Han, S. Manalis

20.345[J] Bioinstrumentation Project Lab
______

Undergrad (Spring)
(Same subject as6.123[J])
Prereq: Biology (GIR), and 2.004 or 6.003; or 20.309; or permission of instructor
Units: 2-7-3
______
In-depth examination of instrumentation design, principles and techniques for studying biological systems, from single molecules to entire organisms. Lectures cover optics, advanced microscopy techniques, electronics for biological measurement, magnetic resonance imaging, computed tomography, MEMs, microfluidic devices, and limits of detection. Students select two lab exercises during the first half of the semester and complete a final design project in the second half. Lab emphasizes design process and skillful realization of a robust system. Enrollment limited; preference to Course 20 majors and minors.
E. Boyden, M. Jonas, S. F. Nagle, P. So, S. Wasserman, M. F. Yanik

20.352 Principles of Neuroengineering
(New)
______

Not offered academic year 2016-2017Undergrad (Fall)
(Subject meets with9.422[J],20.452[J],MAS.881[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Covers how to innovate technologies for brain analysis and engineering, for accelerating the basic understanding of the brain, and leading to new therapeutic insight and inventions. Focuses on using physical, chemical and biological principles to understand technology design criteria governing ability to observe and alter brain structure and function. Topics include optogenetics, noninvasive brain imaging and stimulation, nanotechnologies, stem cells and tissue engineering, and advanced molecular and structural imaging technologies. Includes design projects. Students taking graduate version complete additional assignments. Designed for students with engineering maturity who are ready for design.
E. S. Boyden, III

20.361[J] Molecular and Engineering Aspects of Biotechnology
______

Undergrad (Spring)
(Same subject as7.37[J],10.441[J])
Prereq: 2.005, 3.012, 5.60, or 20.110; 7.06; or permission of instructor
Units: 4-0-8
Credit cannot also be received for7.371
______
Covers biological and bioengineering principles underlying the development and therapeutic use of recombinant proteins and stem cells; glycoengineering of recombinant proteins; normal and pathological signaling by growth factors and their receptors; receptor trafficking; monoclonal antibodies as therapeutics; protein pharmacology and delivery; stem cell-derived tissues as therapeutics; RNA therapeutics; combinatorial protein engineering; and new antitumor drugs.
H. Lodish, L. Griffith

20.363[J] Biomaterials Science and Engineering
______

Undergrad (Fall)
(Same subject as3.055[J])
(Subject meets with3.963[J],20.463[J])
Prereq: 3.034, 20.110, or permission of instructor
Units: 3-0-9
Lecture: MW11-12.30 (56-614)
______
Covers, at a molecular scale, the analysis and design of materials used in contact with biological systems, and biomimetic strategies aimed at creating new materials based on principles found in biology. Topics include molecular interaction between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of materials science to problems in tissue engineering, drug delivery, vaccines, and cell-guiding surfaces. Students taking graduate version complete additional assignments.
D. Irvine, K. Ribbeck
No textbook information available

20.365 Engineering the Immune System in Cancer and Beyond
(New)
______

Undergrad (Spring)
(Subject meets with20.465)
Prereq: 20.110, 5.60, or 7.10; permission of instructor
Units: 3-0-9
______
Examines strategies in clinical and preclinical development for manipulating the immune system to treat and protect against disease. Begins with brief review of immune system. Discusses interaction of tumors with the immune system, followed by approaches by which the immune system can be modulated to attack cancer. Also covers strategies based in biotechnology, chemistry, materials science, and molecular biology to induce immune responses to treat infection, transplantation, and autoimmunity. Students taking graduate version complete additional assignments.
D. Irvine, M. Birnbaum

20.370[J] Cellular Neurophysiology
______

Undergrad (Fall)
(Same subject as2.791[J],6.021[J])
(Subject meets with2.794[J],6.521[J],20.470[J],HST.541[J])
Prereq: Physics II (GIR); 18.03; 2.005, 6.002, 6.003, 6.071, 10.301, 20.110, or permission of instructor
Units: 5-2-5
Lecture: MWF10 (32-144) Lab: TBA Recitation: T12 (34-303) or T4 (34-302) +final
______
Integrated overview of the biophysics of cells from prokaryotes to neurons, with a focus on mass transport and electrical signal generation across cell membrane. First half of course focuses on mass transport through membranes: diffusion, osmosis, chemically mediated, and active transport. Second half focuses on electrical properties of cells: ion transport to action potentials in electrically excitable cells. Synaptic transmission. Electrical properties interpreted via kinetic and molecular properties of single voltage-gated ion channels. Laboratory and computer exercises illustrate the concepts. Students taking graduate version complete different assignments. Preference to juniors and seniors.
J. Han, T. Heldt, J. Voldman
Textbooks (Fall 2016)

20.380 Biological Engineering Design
______

Undergrad (Fall, Spring)
Prereq: 7.06, 20.320, 20.330;Coreq: 20.309
Units: 5-0-7
Lecture: TR10-12 (56-614) Recitation: TR9 (56-614)
______
Illustrates how knowledge and principles of biology, biochemistry, and engineering are integrated to create new products for societal benefit. Uses case study format to examine recently developed products of pharmaceutical and biotechnology industries: how a product evolves from initial idea, through patents, testing, evaluation, production, and marketing. Emphasizes scientific and engineering principles, as well as the responsibility scientists, engineers, and business executives have for the consequences of their technology. Instruction and practice in written and oral communication provided. Enrollment limited; preference to Course 20 undergraduates.
Fall:J. Collins, A. Koehler
Spring:J. Essigmann, K. Ribbeck
No textbook information available

20.385 Understanding Current Research in Synthetic Biology
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with20.020)
Prereq: 20.109, 20.320; or permission of instructor
Units: 3-3-3
______
Provides an in-depth understanding of the state of research in synthetic biology. Critical evaluation of primary research literature covering a range of approaches to the design, modeling and programming of cellular behaviors. Focuses on developing the skills needed to read, present and discuss primary research literature, and to manage and lead small teams. Students mentor a small undergraduate team of 20.020 students. Open to advanced students with appropriate background in biology.
N. Kuldell

20.390[J] Foundations of Computational and Systems Biology
______

Undergrad (Spring)
(Same subject as6.802[J])
(Subject meets with6.874[J],20.490,HST.506[J])
Prereq: Biology (GIR), 6.0002 or 6.01; 7.05; or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/7.91/
______
Provides an introduction to computational and systems biology. Includes units on the analysis of protein and nucleic acid sequences, protein structures, and biological networks. Presents principles and methods used for sequence alignment, motif finding, expression array analysis, structural modeling, structure design and prediction, and network analysis and modeling. Techniques include dynamic programming, Markov and hidden Markov models, Bayesian networks, clustering methods, and energy minimization approaches. Exposes students to emerging research areas. Designed for students with strong backgrounds in either molecular biology or computer science. Some foundational material covering basic programming skills, probability and statistics is provided for students with less quantitative backgrounds. Students taking graduate version complete additional assignments.
D. K. Gifford, T. S. Jaakkola

20.405[J] Principles of Synthetic Biology
______

Graduate (Fall)
(Same subject as6.589[J])
(Subject meets with6.580[J],20.305[J])
Prereq: None
Units: 3-0-9
Lecture: TR11-12.30 (9-057) +final
______
Introduces the basics of synthetic biology, including quantitative cellular network characterization and modeling. Considers the discovery and genetic factoring of useful cellular activities into reusable functions for design. Emphasizes the principles of biomolecular system design and diagnosis of designed systems. Illustrates cutting-edge applications in synthetic biology and enhances skills in analysis and design of synthetic biological applications. Students taking graduate version complete additional assignments.
R. Weiss
No textbook information available

20.409 Biological Engineering II: Instrumentation and Measurement
______

Graduate (Fall, Spring)
(Subject meets with2.673[J],20.309[J])
Prereq: Permission of instructor
Units: 2-7-3
Lecture: TR12 (32-155) Recitation: F12 (56-114)
______
Sensing and measurement aimed at quantitative molecular/cell/tissue analysis in terms of genetic, biochemical, and biophysical properties. Methods include light and fluorescence microscopies, electronic circuits, and electro-mechanical probes (atomic force microscopy, optical traps, MEMS devices). Application of statistics, probability, signal and noise analysis, and Fourier techniques to experimental data. Limited to 5 graduate students.
Fall:P. Blainey, S. Manalis, S. Wasserman, J. Bagnall, E. Frank
Spring:E. Boyden, P. So, S. Wasserman, J. Bagnall, E. Frank
No textbook information available

20.410[J] Molecular, Cellular, and Tissue Biomechanics
______

Graduate (Fall)
(Same subject as2.798[J],3.971[J],6.524[J],10.537[J])
Prereq: Biology (GIR); 2.002, 2.006, 6.013, 10.301, or 10.302
Units: 3-0-9
Lecture: TR10.30-12 (2-143)
______
Develops and applies scaling laws and the methods of continuum mechanics to biomechanical phenomena over a range of length scales. Topics include structure of tissues and the molecular basis for macroscopic properties; chemical and electrical effects on mechanical behavior; cell mechanics, motility and adhesion; biomembranes; biomolecular mechanics and molecular motors. Experimental methods for probing structures at the tissue, cellular, and molecular levels.
R. D. Kamm, K. J. Van Vliet
No textbook information available

20.415 Physical Biology
______

Graduate (Spring)
(Subject meets with20.315)
Prereq: Permission of instructor
Units: 3-0-9
______
Focuses on current major research topics in quantitative, physical biology. Topics include synthetic structural biology, synthetic cell biology, microbial systems biology and evolution, cellular decision making, neuronal circuits, and development and morphogenesis. Emphasizes current motivation and historical background, state-of-the-art measurement methodologies and techniques, and quantitative physical modeling frameworks. Experimental techniques include structural biology, next-generation sequencing, fluorescence imaging and spectroscopy, and quantitative biochemistry. Modeling approaches include stochastic rate equations, statistical thermodynamics, and statistical inference. Students taking graduate version complete additional assignments.
M. Bathe, P. Blainey

20.416[J] Topics in Biophysics and Physical Biology
______

Graduate (Fall)
(Same subject as7.74[J],8.590[J])
Prereq: None
Units: 2-0-4 [P/D/F]
Lecture: F1-2.30 (56-167)
______
Provides broad exposure to research in biophysics and physical biology, with emphasis on the critical evaluation of scientific literature. Weekly meetings include in-depth discussion of scientific literature led by distinct faculty on active research topics. Each session also includes brief discussion of non-research topics including effective presentation skills, writing papers and fellowship proposals, choosing scientific and technical research topics, time management, and scientific ethics.
I. Cisse, N. Fakhri, M. Guo
No required or recommended textbooks

20.420[J] Biomolecular Kinetics and Cellular Dynamics
______

Graduate (Fall)
(Same subject as10.538[J])
Prereq: 7.06, 18.03
Units: 3-0-9
Lecture: TR9.30-11 +final
______
Fundamental analysis of biological rate processes using approaches from biomolecular reaction kinetics and dynamical systems engineering. Topics include binding and hybridization interactions, enzyme reactions, metabolic cycles, gene regulation, receptor/ligand trafficking systems, intra- and intercellular signaling, and cell population dynamics.
A. Jasanoff, E. Fraenkel
No textbook information available

20.430[J] Fields, Forces, and Flows in Biological Systems
______

Graduate (Fall)
(Same subject as2.795[J],6.561[J],10.539[J])
Prereq: 6.013, 2.005, 10.302, or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/beh.430/www/
Lecture: MW1-2.30 (32-124)
______
Molecular diffusion, diffusion-reaction, conduction, convection in biological systems; fields in heterogeneous media; electrical double layers; Maxwell stress tensor, electrical forces in physiological systems. Fluid and solid continua: equations of motion useful for porous, hydrated biological tissues. Case studies of membrane transport, electrode interfaces, electrical, mechanical, and chemical transduction in tissues, convective-diffusion/reaction, electrophoretic, electroosmotic flows in tissues/MEMs, and ECG. Electromechanical and physicochemical interactions in cells and biomaterials; musculoskeletal, cardiovascular, and other biological and clinical examples.
M. Bathe, A. J. Grodzinsky
Textbooks (Fall 2016)

20.440 Analysis of Biological Networks
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 4-0-8
______
Conceptual and experimental approaches to analyzing complex biological networks and systems, from molecules to human populations, focusing on human pathophysiology and disease. Moving from single component analysis to pathways and networks, combines didactic lectures with in-depth analysis of current literature. Emphasizes the chemistry and biochemistry of underlying biological processes. Topics include linking genes/SNPs to disease, defining pathways, analysis of pathways in vivo, systems-level analysis, and applications of network biology. First half of term focuses on fundamental biological processes and tools/analyses needed by biological engineers, and the second half elaborates on these fundamentals by covering complex biological processes. Students acquire skills in the fundamentals of grant preparation using an NIH format and make an oral presentation.
P. Blainey, E. Fraenkel, M. Yaffe

20.445[J] Methods and Problems in Microbiology
______

Graduate (Fall)
(Same subject as1.86[J],7.492[J])
Prereq: None
Units: 3-0-9
Lecture: W EVE (3-6 PM) (4-146)
______
Students will read and discuss primary literature covering key areas of microbial research with emphasis on methods and approaches used to understand and manipulate microbes. Preference to first-year Microbiology and Biology students.
M. Laub
No required or recommended textbooks

20.446[J] Microbial Genetics and Evolution
______

Graduate (Fall)
(Same subject as1.87[J],7.493[J],12.493[J])
Prereq: 7.03, 7.05, or permission of instructor
Units: 4-0-8
Lecture: TR12.30-2.30 (66-160)
______
Covers aspects of microbial genetic and genomic analyses, central dogma, horizontal gene transfer, and evolution.
A. D. Grossman, G. Fournier
Textbooks (Fall 2016)

20.450 Molecular and Cellular Pathophysiology
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 20.420, 20.440; or permission of instructor
Units: 4-0-8
Subject Cancelled Subject Cancelled
______
Compares the complex molecular and cellular interactions in health and disease between commensal microbial communities, pathogens and the human or animal host. Special focus is given to current research on microbe/host interactions, infection of significant importance to public health, and chronic infectious disease. Classwork will include lecture, but emphasize critical evaluation and class discussion of recent scientific papers, and the development of new research agendas in the fields presented.
J. C. Niles, J. Runstadler

20.452[J] Principles of Neuroengineering
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as9.422[J],MAS.881[J])
(Subject meets with20.352)
Prereq: Permission of instructor
Units: 3-0-9
URL: http://neuro.media.mit.edu/classes/prinneuro/
______
Covers how to innovate technologies for brain analysis and engineering, for accelerating the basic understanding of the brain, and leading to new therapeutic insight and inventions. Focuses on using physical, chemical and biological principles to understand technology design criteria governing ability to observe and alter brain structure and function. Topics include optogenetics, noninvasive brain imaging and stimulation, nanotechnologies, stem cells and tissue engineering, and advanced molecular and structural imaging technologies. Includes design projects. Designed for students with engineering maturity who are ready for design. Students taking graduate version complete additional assignments.
E. S. Boyden, III

20.454[J] Revolutionary Ventures: How to Invent and Deploy Transformative Technologies
______

Graduate (Fall)
(Same subject as9.455[J],15.128[J],MAS.883[J])
Prereq: Permission of instructor
Units: 2-0-7
URL: http://neuro.media.mit.edu/classes/neuroven/
Lecture: R2-4 (E15-341)
______
Seminar on envisioning and building ideas and organizations to accelerate engineering revolutions. Focuses on emerging technology domains, such as neurotechnology, imaging, cryotechnology, gerontechnology, and bio-and-nano fabrication. Draws on historical examples as well as live case studies of existing or emerging organizations, including labs, institutes, startups, and companies. Goals range from accelerating basic science to developing transformative products or therapeutics. Each class is devoted to a specific area, often with invited speakers, exploring issues from the deeply technical through the strategic. Individually or in small groups, students prototype new ventures aimed at inventing and deploying revolutionary technologies.
J. Bonsen, J. Jacobson
No textbook information available

20.463[J] Biomaterials Science and Engineering
______

Graduate (Fall)
(Same subject as3.963[J])
(Subject meets with3.055[J],20.363[J])
Prereq: 3.034, 20.110, or permission of instructor
Units: 3-0-9
Lecture: MW11-12.30 (56-614)
______
Covers, at a molecular scale, the analysis and design of materials used in contact with biological systems, and biomimetic strategies aimed at creating new materials based on principles found in biology. Topics include molecular interaction between bio- and synthetic molecules and surfaces; design, synthesis, and processing approaches for materials that control cell functions; and application of materials science to problems in tissue engineering, drug delivery, vaccines, and cell-guiding surfaces. Students taking graduate version complete additional assignments.
D. Irvine, K. Ribbeck
No textbook information available

20.465 Engineering the Immune System in Cancer and Beyond
(New)
______

Graduate (Spring)
(Subject meets with20.365)
Prereq: Permission of instructor
Units: 3-0-9
______
Examines strategies in clinical and preclinical development for manipulating the immune system to treat and protect against disease. Begins with brief review of immune system. Discusses interaction of tumors with the immune system, followed by approaches by which the immune system can be modulated to attack cancer. Also covers strategies based in biotechnology, chemistry, materials science, and molecular biology to induce immune responses to treat infection, transplantation, and autoimmunity. Students taking graduate version complete additional assignments.
D. Irvine, M. Birnbaum

20.470[J] Cellular Neurophysiology
______

Graduate (Fall)
(Same subject as2.794[J],6.521[J],HST.541[J])
(Subject meets with2.791[J],6.021[J],20.370[J])
Prereq: Physics II (GIR); 18.03; 2.005, 6.002, 6.003, 6.071, 10.301, 20.110, or permission of instructor
Units: 5-2-5
Lecture: MWF10 (32-144) Lab: TBA Recitation: T12 (34-303) or T4 (34-302) +final
______
Meets with undergraduate subject 6.021J. Requires the completion of more advanced home problems and/or an additional project.
J. Han, T. Heldt
Textbooks (Fall 2016)

20.482[J] Foundations of Algorithms and Computational Techniques in Systems Biology
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as6.581[J])
(Subject meets with6.503)
Prereq: 6.021, 6.034, 6.046, 6.336, 18.417, or permission of instructor
Units: 3-0-9
______
Illustrates computational approaches to solving problems in systems biology. Uses a series of case studies to demonstrate how an effective match between the statement of a biological problem and the selection of an appropriate algorithm or computational technique can lead to fundamental advances. Covers several discrete and numerical algorithms used in simulation, feature extraction, and optimization for molecular, network, and systems models in biology. Students taking graduate version complete additional assignments.
B. Tidor, J. K. White

20.483[J] Noninvasive Imaging in Biology and Medicine
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as9.173[J],22.56[J],HST.561[J])
Prereq: 18.03, 8.03, or permission of instructor
Units: 3-0-9
______
Background in the theory and application of noninvasive imaging methods in biology and medicine, with emphasis on neuroimaging. Focuses on the modalities most frequently used in scientific research (x-ray CT, PET/SPECT, MRI, and optical imaging), and includes discussion of molecular imaging approaches used in conjunction with these scanning methods. Lectures are supplemented by in-class discussions of problems in research and demonstrations of imaging systems.
A. Jasanoff

20.486[J] Case Studies and Strategies in Drug Discovery and Development
______

Graduate (Spring)
(Same subject as7.549[J],15.137[J],HST.916[J])
Prereq: None
Units: 2-0-4
______
Aims to develop appreciation for the stages of drug discovery and development, from target identification, to the submission of preclinical and clinical data to regulatory authorities for marketing approval. Following introductory lectures on the process of drug development, students working in small teams analyze how one of four new drugs or drug candidates traversed the discovery/development landscape. For each case, an outside expert from the sponsoring drug company or pivotal clinical trial principal investigator provides guidance and critiques the teams' presentations to the class.
S. R. Tannenbaum, A. J. Sinskey, A. W. Wood

20.487[J] Optical Microscopy and Spectroscopy for Biology and Medicine
______

Graduate (Spring)
Not offered regularly; consult department
(Same subject as2.715[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces the theory and the design of optical microscopy and its applications in biology and medicine. The course starts from an overview of basic optical principles allowing an understanding of microscopic image formation and common contrast modalities such as dark field, phase, and DIC. Advanced microscopy imaging techniques such as total internal reflection, confocal, and multiphoton will also be discussed. Quantitative analysis of biochemical microenvironment using spectroscopic techniques based on fluorescence, second harmonic, Raman signals will be covered. We will also provide an overview of key image processing techniques for microscopic data.
P. T. So, C. Sheppard

20.490 Foundations of Computational and Systems Biology
______

Graduate (Spring)
(Subject meets with6.802[J],6.874[J],20.390[J],HST.506[J])
Prereq: Biology (GIR), 6.0002 or 6.01; or 7.05; or permission of instructor
Units: 3-0-9
URL: http://web.mit.edu/7.91/
______
Provides an introduction to computational and systems biology. Includes units on the analysis of protein and nucleic acid sequences, protein structures, and biological networks. Presents principles and methods used for sequence alignment, motif finding, expression array analysis, structural modeling, structure design and prediction, and network analysis and modeling. Techniques include dynamic programming, Markov and hidden Markov models, Bayesian networks, clustering methods, and energy minimization approaches. Exposes students to emerging research areas. Designed for students with strong backgrounds in either molecular biology or computer science. Some foundational material covering basic programming skills, probability and statistics is provided for students with less quantitative backgrounds. Students taking graduate version complete additional assignments.
D. K. Gifford, T. S. Jaakkola

20.507[J] Biological Chemistry I
______

Undergrad (Fall) Rest Elec in Sci & Tech
(Same subject as5.07[J])
Prereq: 5.12
Units: 5-0-7
Credit cannot also be received for7.05
Lecture: MWF9 (4-370) Recitation: MW1 (36-372) or MW2 (36-372) or TR10 (36-144) or TR11 (36-144) +final
______
Chemical and physical properties of the cell and its building blocks. Structures of proteins and principles of catalysis. The chemistry of organic/inorganic cofactors required for chemical transformations within the cell. Basic principles of metabolism and regulation in pathways, including glycolysis, gluconeogenesis, fatty acid synthesis/degradation, pentose phosphate pathway, Krebs cycle and oxidative phosphorylation, DNA replication, and transcription and translation.
E. Nolan, A. Klibanov
Textbooks (Fall 2016)

20.554[J] Frontiers in Chemical Biology
______

Graduate (Fall)
(Same subject as5.54[J],7.540[J])
Prereq: 5.13, 5.07, 7.06, permission of instructor
Units: 2-0-4
Lecture: R8.30-10 (4-231)
______
Introduction to current research at the interface of chemistry, biology, and bioengineering. Topics include imaging of biological processes, metabolic pathway engineering, protein engineering, mechanisms of DNA damage, RNA structure and function, macromolecular machines, protein misfolding and disease, metabolomics, and methods for analyzing signaling network dynamics. Lectures are interspersed with class discussions and student presentations based on current literature.
M. Shoulders
No textbook information available

20.560 Statistics for Biological Engineering
______

Graduate (IAP)
Prereq: Permission of instructor
Units: 2-0-2 [P/D/F]
______
Provides basic tools for analyzing experimental data, interpreting statistical reports in the literature, and reasoning under uncertain situations. Topics include probability theory, statistical tests, data exploration, Bayesian statistics, and machine learning. Emphasizes discussion and hands-on learning. Experience with MATLAB, Python, or R recommended.
S. Olesen

20.902 Independent Study in Biological Engineering
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Opportunity for independent study under regular supervision by a faculty member. Projects require prior approval, as well as a substantive paper. Minimum 12 units required.
Staff
No textbook information available

20.903 Independent Study in Biological Engineering
______

Undergrad (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
TBA.
______
Opportunity for independent study under regular supervision by a faculty member. Projects require prior approval, as well as a substantive paper. Minimum 6-12 units required.
Staff
No textbook information available

20.920 Practical Work Experience
______

Undergrad (Fall, IAP, Spring, Summer)
Prereq: None
Units: 0-1-0 [P/D/F]
TBA.
______
For Course 20 students participating in off-campus work experiences in biological engineering. Before registering for this subject, students must have an employment offer from a company or organization and must identify a BE supervisor. Upon completion of the work, student must submit a letter from the employer describing the work accomplished, along with a substantive final report from the student approved by the MIT supervisor. Subject to departmental approval. Consult departmental undergraduate office.
Staff
No textbook information available

20.950 Research Problems in Biological Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Directed research in the fields of bioengineering and environmental health. Limited to BE students.
Staff
No textbook information available

20.951 Thesis Proposal
______

Graduate (Fall, Spring, Summer)
Prereq: Permission of instructor
Units: 0-24-0 [P/D/F]
TBA.
______
Thesis proposal research and presentation to the thesis committee.
Staff
No textbook information available

20.960 Teaching Experience in Biological Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
For qualified graduate students interested in teaching. Tutorial, laboratory, or classroom teaching under the supervision of a faculty member. Enrollment limited by availability of suitable teaching assignments.
Staff
No textbook information available

20.BME Undergraduate Research in Biomedical Engineering
(New)
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Individual research project with biomedical or clinical focus, arranged with appropriate faculty member or approved supervisor. Forms and instructions for the proposal and final report are available in the BE Undergraduate Office.
Consult BE Department
No textbook information available

20.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No textbook information available

20.S900 Special Subject in Biological Engineering
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
Lecture: W9 (4-270)
______
No textbook information available

20.S940 Special Subject in Biological Engineering
______

Undergrad (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Detailed discussion of selected topics of current interest. Classwork in various areas not covered by regular subjects.
Staff
No textbook information available

20.S947-20.S949 Special Subject in Biological Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
20.S947: Lecture: F2 (56-180)
20.S948: TBA.
20.S949: TBA.
______
20.S947: No textbook information available
20.S948: No textbook information available
20.S949: No textbook information available

20.S952 Special Subject in Biological Engineering
______

Graduate (Fall, Spring) Can be repeated for credit
Prereq: Permission of instructor
Units arranged [P/D/F]
Lecture: R EVE (4-6 PM) (32-141)
______
Detailed discussion of selected topics of current interest. Classwork in various areas not covered by regular subjects.
Staff
No textbook information available

20.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research leading to the writing of an SM or PhD thesis; to be arranged by the student and the MIT faculty advisor.
Staff
Textbooks arranged individually

20.UR Undergraduate Research Opportunities
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Laboratory research in the fields of bioengineering or environmental health. May be extended over multiple terms.
S. Manalis
Textbooks arranged individually

20.URG Undergraduate Research Opportunities
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
Emphasizes direct and active involvement in laboratory research in bioengineering or environmental health. May be extended over multiple terms.
Consult S. Manalis
Textbooks arranged individually


left arrow|20.00-20.ZZZZ|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 22: Nuclear Science and Engineering
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Course 22: Nuclear Science and Engineering
Fall 2016


Undergraduate Subjects

22.00 Introduction to Modeling and Simulation
______

Undergrad (Spring) Rest Elec in Sci & Tech
Engineering School-Wide Elective Subject.
(Offered under:1.021,3.021,10.333,22.00)
Prereq: 18.03, 3.016, or permission of instructor
Units: 4-0-8
______
Basic concepts of computer modeling and simulation in science and engineering. Uses techniques and software for simulation, data analysis and visualization. Continuum, mesoscale, atomistic and quantum methods used to study fundamental and applied problems in physics, chemistry, materials science, mechanics, engineering, and biology. Examples drawn from the disciplines above are used to understand or characterize complex structures and materials, and complement experimental observations.
M. Buehler, R. Taylor

22.01 Introduction to Nuclear Engineering and Ionizing Radiation
______

Undergrad (Fall) Rest Elec in Sci & Tech
Prereq: None
Units: 5-0-7
Lecture: TR9,F1 (24-115) Recitation: F2-4 (24-307) +final
______
Provides an introduction to nuclear science and its engineering applications. Describes basic nuclear models, radioactivity, nuclear reactions and kinematics. Covers the interaction of ionizing radiation with matter, with an emphasis on radiation detection, radiation shielding, and radiation effects on human health. Presents energy systems based on fission and fusion nuclear reactions, as well as industrial and medical applications of nuclear science.
M. Short
Textbooks (Fall 2016)

22.011 Seminar in Nuclear Science and Engineering
______

Undergrad (Fall)
Prereq: None
Units: 2-0-4
Lecture: T3-5 (24-112)
______
Surveys the range of diverse subjects in nuclear science and engineering covered by the department. Topics include quantum computing, energy and power, radiation effects-stem cells and DNA, BNCT, nuclear space applications, fusion, airport security, accelerators, magnetic resonance imaging, non-proliferation, risk assessment, safety, biology and medicine. A demonstration of the MIT Reactor as a research tool is given as well as a tour of the MIT Tokomak fusion machine and accelerators used in research.
Z. Hartwig
No textbook information available

22.012 Seminar in Fusion and Plasma Physics
______

Undergrad (Spring)
Prereq: None
Units: 2-0-4
URL: http://web.mit.edu/22.012/www/
______
Lectures and discussion introducing the range of topics relevant to plasma physics and fusion engineering. Introductory discussion of the economic and ecological motivation for the development of fusion power. Contemporary magnetic confinement schemes, theoretical questions, and engineering considerations are presented by expert guest lecturers. Includes visit to Plasma Science and Fusion Center experimental facilities.
D. Whyte

22.014 Ethics for Engineers
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.082,2.900,6.904,10.01,22.014)
Prereq: None
Units: 2-0-4
Lecture: M3-5 (66-144, 36-153) or T3-5 (37-212) or T EVE (7.30-9.30 PM) (66-144) or W3-5 (36-153)
______
Integrates classical readings that provide an overview of ethics with a survey of case studies that focus on ethical problems arising in the practice of engineering. Readings taken from a variety of sources, such as Aristotle, Machiavelli, Bacon, Hobbes, Locke, the Founding Fathers, and the Bible. Case studies include written analyses and films that address engineering disasters, biotechnology, court cases, ethical codes, and the ultimate scope and aims of engineering.
D. Doneson, B. L. Trout
No required or recommended textbooks

22.02 Introduction to Applied Nuclear Physics
______

Undergrad (Spring) Rest Elec in Sci & Tech
Prereq: Physics II (GIR), Calculus II (GIR); 8.03 or permission of instructor
Units: 5-0-7
______
Covers basic concepts of nuclear physics with emphasis on nuclear structure and interactions of radiation with matter. Topics include elementary quantum theory; nuclear forces; shell structure of the nucleus; alpha, beta and gamma radioactive decays; interactions of nuclear radiations (charged particles, gammas, and neutrons) with matter; nuclear reactions; fission and fusion.
P. Cappellaro

22.033 Nuclear Systems Design Project
______

Undergrad (Fall)
(Subject meets with22.33)
Prereq: None
Units: 3-0-12
Lecture: MWF11 (24-115)
______
Group design project involving integration of nuclear physics, particle transport, control, heat transfer, safety, instrumentation, materials, environmental impact, and economic optimization. Provides opportunity to synthesize knowledge acquired in nuclear and non-nuclear subjects and apply this knowledge to practical problems of current interest in nuclear applications design. Past projects have included using a fusion reactor for transmutation of nuclear waste, design and implementation of an experiment to predict and measure pebble flow in a pebble bed reactor, and development of a mission plan for a manned Mars mission including the conceptual design of a nuclear powered space propulsion system and power plant for the Mars surface, a lunar/Martian nuclear power station and the use of nuclear plants to extract oil from tar sands. Students taking graduate version complete additional assignments.
M. Short, A. White
No required or recommended textbooks

22.04[J] Social Problems of Nuclear Energy
______

Not offered academic year 2016-2017Undergrad (Fall) HASS Social Sciences
(Same subject asSTS.084[J])
Prereq: None
Units: 3-0-9
______
Surveys the major social challenges for nuclear energy. Topics include the ability of nuclear power to help mitigate climate change; challenges associated with ensuring nuclear safety; the effects of nuclear accidents; the management of nuclear waste; the linkages between nuclear power and nuclear weapons, the consequences of nuclear war; and political challenges to the safe and economic regulation of the nuclear industry. Weekly readings presented from both sides of the debate, followed by in-class discussions. Instruction and practice in oral and written communication provided. Limited to 18.
R. S. Kemp

22.05 Neutron Science and Reactor Physics
______

Undergrad (Fall)
Prereq: 18.03, 22.01, 22.06
Units: 5-0-7
Lecture: TR11-12.30 (24-115) Recitation: F9-11 (24-115) +final
______
Introduces fundamental properties of the neutron. Covers reactions induced by neutrons, nuclear fission, slowing down of neutrons in infinite media, diffusion theory, the few-group approximation, point kinetics, and fission-product poisoning. Emphasizes the nuclear physics bases of reactor design and its relationship to reactor engineering problems.
B. Forget
Textbooks (Fall 2016)

22.054[J] Materials Performance in Extreme Environments
______

Not offered academic year 2016-2017Undergrad (Spring)
(Same subject as3.154[J])
Prereq: 3.032, 3.044
Units: 3-2-7
______
Studies the behavior of materials in extreme environments typical of those in which advanced energy systems (including fossil, nuclear, solar, fuel cells, and battery) operate. Takes both a science and engineering approach to understanding how current materials interact with their environment under extreme conditions. Explores the role of modeling and simulation in understanding material behavior and the design of new materials. Focuses on energy and transportation related systems.
R. Ballinger

22.055 Radiation Biophysics
______

Not offered academic year 2016-2017Undergrad (Spring)
(Subject meets with22.55[J],HST.560[J])
Prereq: Permission of instructor
Units: 3-0-9
______
Provides a background in sources of radiation with an emphasis on terrestrial and space environments and on industrial production. Discusses experimental approaches to evaluating biological effects resulting from irradiation regimes differing in radiation type, dose and dose-rate. Effects at the molecular, cellular, organism, and population level are examined. Literature is reviewed identifying gaps in our understanding of the health effects of radiation, and responses of regulatory bodies to these gaps is discussed. Students taking graduate version complete additional assignments.
Staff

22.06 Engineering of Nuclear Systems
______

Undergrad (Spring)
Prereq: 2.005
Units: 3-0-9
______
Using the basic principles of reactor physics, thermodynamics, fluid flow and heat transfer, students examine the engineering design of nuclear power plants. Emphasizes light-water reactor technology, thermal limits in nuclear fuels, thermal-hydraulic behavior of the coolant, nuclear safety and dynamic response of nuclear power plants.
E. Baglietto

22.071[J] Electronics, Signals, and Measurement
______

Undergrad (Spring) Rest Elec in Sci & Tech
(Same subject as6.071[J])
Prereq: 18.03
Units: 3-3-6
______
Provides the knowledge necessary for reading schematics and designing, building, analyzing, and testing fundamental analog and digital circuits. Students construct interactive examples and explore the practical uses of electronics in engineering and experimental science, including signals and measurement fundamentals. Uses state-of-the-art hardware and software for data acquisition, analysis, and control. Suitable for students with little or no previous background in electronics.
A. White

22.081[J] Introduction to Sustainable Energy
______

Undergrad (Fall)
(Same subject as2.650[J],10.291[J])
(Subject meets with1.818[J],2.65[J],10.391[J],11.371[J],22.811[J])
Prereq: Permission of instructor
Units: 3-1-8
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various renewable and conventional energy production technologies, energy end-use practices and alternatives, and consumption practices in different countries. Investigates their attributes within a quantitative analytical framework for evaluation of energy technology system proposals. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments. Limited to juniors and seniors.
M. W. Golay
Textbooks (Fall 2016)

22.09 Principles of Nuclear Radiation Measurement and Protection
______

Undergrad (Fall) Institute Lab
(Subject meets with22.90)
Prereq: 22.01
Units: 2-6-4
Lecture: M1-3 (NW12-222) Lab: W12-3 (NW12-222) or F12-3 (NW12-222)
______
Combines lectures, demonstrations, and experiments. Review of radiation protection procedures and regulations; theory and use of alpha, beta, gamma, and neutron detectors; applications in imaging and dosimetry; gamma-ray spectroscopy; design and operation of automated data acquisition experiments using virtual instruments. Meets with graduate subject 22.90, but homework assignments and examinations differ. Instruction and practice in written communication provided.
A. Danagoulian, G. Kohse
No textbook information available

22.091, 22.093 Independent Project in Nuclear Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
22.091: TBA.
22.093: TBA.
______
For undergraduates who wish to conduct a one-term project of theoretical or experimental nature in the field of nuclear engineering, in close cooperation with individual staff members. Topics and hours arranged to fit students' requirements. Projects require prior approval by the Course 22 Undergraduate Office. 22.093 is graded P/D/F.
M. Short
22.091: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
22.093: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

22.S092-22.S094 Special Subject in Nuclear Science and Engineering
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
22.S092: TBA.
22.S093: TBA.
22.S094: TBA.
______
Seminar or lecture on a topic in nuclear science and engineering that is not covered in the regular curriculum.
M. Short
22.S092: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
22.S093: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
22.S094: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

22.EPE UPOP Engineering Practice Experience
______

Undergrad (Fall, Spring)
Engineering School-Wide Elective Subject.
(Offered under:1.EPE,2.EPE,3.EPE,6.EPE,10.EPE,16.EPE,22.EPE)
Prereq: 2.EPW or permission of instructor
Units: 0-0-1 [P/D/F]
TBA.
______
Provides sophomores with guided practice in finding opportunities and excelling in the world of practice. Building on the skills and relationships acquired in the Engineering Practice Workshop, students receive coaching to articulate goals, invoke the UPOP network of mentors and employers, identify and pursue opportunities and negotiate terms of their summer assignment. Students complete a 10-12 week internship, which includes filing three progress reports, conducting one informational interview, and possibly hosting a site visit by MIT staff. Returning to campus as juniors, UPOP students take part in reflective exercises that aid assimilation of learning objectives and reinforce the cognitive link between all aspects of the UPOP experience and disciplinary fields of study. Sequence begins in the spring of sophomore year and ends in the fall of junior year.
Staff
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

22.EPW UPOP Engineering Practice Workshop
______

Undergrad (Fall, IAP)
Engineering School-Wide Elective Subject.
(Offered under:1.EPW,2.EPW,3.EPW,6.EPW,10.EPW,16.EPW,20.EPW,22.EPW)
Prereq: None
Units: 1-0-0 [P/D/F]
TBA.
______
Develops foundational skills for the world of practice in science, technology, and engineering. Sophomores receive classroom instruction, and one-on-one and small-group coaching in basics of professional identity building. They attend field trips to local employers and receive job interview practice, coached by industry volunteers. Over IAP, students attend a weeklong Team Training Camp of experiential learning modules - led by MIT faculty with the help of MIT alums and other senior professionals in business, engineering, and science where students participate in creative simulations, team problem-solving challenges, and oral presentations, and practice networking with employers. Enrollment limited.
Staff
No required or recommended textbooks

22.THT Undergraduate Thesis Tutorial
______

Undergrad (Fall)
Prereq: None
Units: 1-0-2 [P/D/F]
Lecture: F3 (24-121)
______
A series of lectures on prospectus and thesis writing. Students select a thesis topic and a thesis advisor who reviews and approves the prospectus for thesis work in the spring term.
R. Lester, B. Yildiz
No required or recommended textbooks

22.THU Undergraduate Thesis
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: 22.THT
Units arranged
TBA.
______
Program of research, leading to the writing of an SB thesis, to be arranged by the student and appropriate MIT faculty member. See department undergraduate headquarters.
M. Short
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

22.UR Undergraduate Research Opportunities Program
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged [P/D/F]
TBA.
______
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)

22.URG Undergraduate Research Opportunities Program
______

Undergrad (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: None
Units arranged
TBA.
______
The Undergraduate Research Opportunities Program is an excellent way for undergraduate students to become familiar with the department of Nuclear Science and Engineering. Student research as a UROP project has been conducted in areas of fission reactor studies, utilization of fusion devices, applied radiation physics research, and biomedical applications. Projects include the study of engineering aspects for fusion and fission energy sources, and utilization of radiations.
M. Short
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


left arrow|22.00-22.099 plus UROP, UPOP, and ThU|22.101-22.599|22.60-22.THG|right arrow



Produced: 29-SEP-2016 06:37 AMFall 2016 Course 22: Nuclear Science and Engineering
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Course 22: Nuclear Science and Engineering
Fall 2016


Graduate Subjects

22.107 Computational Nuclear Science and Engineering
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 18.085, 22.00, or permission of instructor
Units: 3-0-9
______
Develops practical scientific computing skills with applications in radiation physics, reactor engineering and design, nuclear materials, fusion, etc. Topics include compiling/profiling/time and memory complexities/debugging, solvers of ordinary differential equations and partial differential equations, error versus stability, and pre-and post-processing. Includes a survey of visualization and parallel computing and case studies in quantum mechanics, neutron diffusion and transport, simple CFD, and radiation cascade simulations. Assignments require programming in one or several languages of choice; some MATLAB-free assignments also required.
J. Li

22.11 Applied Nuclear Physics
______

Graduate (Fall) Can be repeated for credit; first half of term
Prereq: 22.02 or permission of instructor
Units: 2-0-4
Ends Oct 21. Lecture: TR9.30-11 (24-121)
______
Introduction to nuclear structure, reactions, and radioactivity. Review of quantization, the wave function, angular momentum and tunneling. Simplified application to qualitative understanding of nuclear structure. Stable and unstable isotopes, radioactive decay, decay products and chains. Nuclear reactions, cross-sections, and fundamental forces, and the resulting phenomena.
B. Yildiz
Textbooks (Fall 2016)

22.12 Radiation Interactions, Control, and Measurement
______

Graduate (Fall) Can be repeated for credit; second half of term
Prereq: 8.02 or permission of instructor
Units: 2-0-4
Begins Oct 24. Lecture: TR9.30-11 (24-121) +final
______
The interaction, attenuation, and biological effects of penetrating radiation, especially neutrons and photons. Physical processes of radiation scattering and absorption, and their cross-sections. Outline of health physics. Biological effects of radiation, and its quantification. Principles of radiation shielding, detection, dosimetry and radiation protection.
A. Danagoulian
No textbook information available

22.13 Nuclear Energy Systems
______

Graduate (Spring) Can be repeated for credit; first half of term
Prereq: 22.01, 2.005, or permission of instructor
Units: 2-0-4
______
Introduction to generation of energy from nuclear reactions. Characteristics of nuclear energy. Fission cross-sections, criticality, and reaction control. Basic considerations of fission reactor engineering, thermal hydraulics, and safety. Nuclear fuel and waste characteristics. Fusion reactions and the character and conditions of energy generation. Plasma physics and approaches to achieving terrestrial thermonuclear fusion energy.
B. Forget

22.14 Materials in Nuclear Engineering
______

Graduate (Spring) Can be repeated for credit; first half of term
Prereq: Chemistry (GIR) or permission of instructor
Units: 2-0-4
______
Introduces the fundamental phenomena of materials science with special attention to radiation and harsh environments. Materials lattices and defects and the consequent understanding of strength of materials, fatigue, cracking, and corrosion. Coulomb collisions of charged particles; their effects on structured materials; damage and defect production, knock-ons, transmutation, cascades and swelling. Materials in fission and fusion applications: cladding, waste, plasma-facing components, blankets.
J. Li

22.15 Essential Numerical Methods
______

Graduate (Fall) Can be repeated for credit; first half of term
Prereq: 12.010 or permission of instructor
Units: 2-0-4
Ends Oct 28. Lecture: MW9.30-11 (24-115) Recitation: MW9-9.30 (24-115)
______
Introduces computational methods for solving physical problems in nuclear applications. Ordinary and partial differential equations for particle orbit, and fluid, field, and particle conservation problems; their representation and solution by finite difference numerical approximations. Iterative matrix inversion methods. Stability, convergence, accuracy and statistics. Particle representations of Boltzmann's equation and methods of solution such as Monte-Carlo and particle-in-cell techniques.
N. Louriero
Textbooks (Fall 2016)

22.16 Nuclear Technology and Society
______

Graduate (Spring) Can be repeated for credit; second half of term
Prereq: 22.01 or permission of instructor
Units: 2-0-4
______
Introduces the societal context and challenges for nuclear technology. Major themes include economics and valuation of nuclear power, interactions with government and regulatory frameworks; safety, quantification of radiation hazards, and public attitudes to risk. Covers policies and methods for limiting nuclear-weapons proliferation, including nuclear detection, materials security and fuel-cycle policy.
R. S. Kemp

Nuclear Reactor Physics

22.211 Nuclear Reactor Physics I
______

Graduate (Spring)
Prereq: 22.05
Units: 3-0-9
______
Provides an overview of reactor physics methods for core design and analysis. Topics include nuclear data, neutron slowing down, homogeneous and heterogeneous resonance absorption, calculation of neutron spectra, determination of group constants, nodal diffusion methods, Monte Carlo simulations of reactor core reload design methods.
K. Smith

22.212 Nuclear Reactor Analysis II
______

Graduate (Fall)
Prereq: 22.211
Units: 3-2-7
Lecture: MW1-2.30 (24-115)
______
Addresses advanced topics in nuclear reactor physics with an additional focus towards computational methods and algorithms for neutron transport. Covers current methods employed in lattice physics calculations, such as resonance models, critical spectrum adjustments, advanced homogenization techniques, fine mesh transport theory models, and depletion solvers. Also presents deterministic transport approximation techniques, such as the method of characteristics, discrete ordinates methods, and response matrix methods.
K. Smith
No textbook information available

22.213 Nuclear Reactor Physics III
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 22.211
Units: 3-0-9
______
Covers numerous high-level topics in nuclear reactor analysis methods and builds on the student's background in reactor physics to develop a deep understanding of concepts needed for time-dependent nuclear reactor core physics, including coupled non-linear feedback effects. Introduces numerical algorithms needed to solve real-world time-dependent reactor physics problems in both diffusion and transport. Additional topics include iterative numerical solution methods (e.g., CG, GMRES, JFNK, MG), nonlinear accelerator methods, and numerous modern time-integration techniques.
K. Smith, B. Forget

22.251 Systems Analysis of the Nuclear Fuel Cycle
______

Not offered academic year 2017-2018Graduate (Fall)
Prereq: 22.05
Units: 3-2-7
Lecture: TR1-2.30 (24-115)
______
Study of the relationship between the technical and policy elements of the nuclear fuel cycle. Topics include uranium supply, enrichment, fuel fabrication, in-core reactivity and fuel management of uranium and other fuel types, used fuel reprocessing and waste disposal. Principles of fuel cycle economics and the applied reactor physics of both contemporary and proposed thermal and fast reactors are presented. Nonproliferation aspects, disposal of excess weapons plutonium, and transmutation of long lived radioisotopes in spent fuel are examined. Several state-of-the-art computer programs relevant to reactor core physics and heat transfer are provided for student use in problem sets and term papers.
C. Forsberg
No textbook information available

Nuclear Reactor Engineering

22.312 Engineering of Nuclear Reactors
______

Graduate (Spring)
Prereq: 2.001, 2.005; or permission of instructor
Units: 3-0-9
______
Engineering principles of nuclear reactors, emphasizing power reactors. Power plant thermodynamics, reactor heat generation and removal (single-phase as well as two-phase coolant flow and heat transfer), and structural mechanics. Engineering considerations in reactor design.
J. Buongiorno

22.313[J] Thermal Hydraulics in Power Technology
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as 2.59[J],10.536[J])
Prereq: 2.006, 10.302, 22.312, or permission of instructor
Units: 3-2-7
______
Emphasis on thermo-fluid dynamic phenomena and analysis methods for conventional and nuclear power stations. Kinematics and dynamics of two-phase flows. Steam separation. Boiling, instabilities, and critical conditions. Single-channel transient analysis. Multiple channels connected at plena. Loop analysis including single and two-phase natural circulation. Subchannel analysis.
E. Baglietto

22.314[J] Structural Mechanics in Nuclear Power Technology
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as1.56[J],2.084[J])
Prereq: 2.001 or permission of instructor
Units: 3-0-9
______
Structural components in nuclear power plant systems, their functional purposes, operating conditions, and mechanical/structural design requirements. Combines mechanics techniques with models of material behavior to determine adequacy of component design. Considerations include mechanical loading, brittle fracture, inelastic behavior, elevated temperatures, neutron irradiation, vibrations and seismic effects.
Staff

22.315 Applied Computational Fluid Dynamics and Heat Transfer
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Focuses on the application of computational fluid dynamics to the analysis of power generation and propulsion systems, and on industrial and chemical processes in general. Discusses simulation methods for single and multiphase applications and their advantages and limitations in industrial situations. Students practice breaking down an industrial problem into its modeling challenges, designing and implementing a plan to optimize and validate the modeling approach, performing the analysis, and quantifying the uncertainty margin.
E. Baglietto

22.33 Nuclear Engineering Design
______

Graduate (Fall)
(Subject meets with22.033)
Prereq: 22.312
Units: 3-0-15
Lecture: MWF11 (24-115)
______
Group design project involving integration of nuclear physics, particle transport, control, heat transfer, safety, instrumentation, materials, environmental impact, and economic optimization. Provides opportunity to synthesize knowledge acquired in nuclear and non-nuclear subjects and apply this knowledge to practical problems of current interest in nuclear applications design. Past projects have included using a fusion reactor for transmutation of nuclear waste, design and implementation of an experiment to predict and measure pebble flow in a pebble bed reactor, and development of a mission plan for a manned Mars mission including the conceptual design of a nuclear powered space propulsion system and power plant for the Mars surface. Students taking graduate version complete additional assignments.
M. Short, A. White
No textbook information available

22.38 Probability and Its Applications To Reliability, Quality Control, and Risk Assessment
______

Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Interpretations of the concept of probability. Basic probability rules; random variables and distribution functions; functions of random variables. Applications to quality control and the reliability assessment of mechanical/electrical components, as well as simple structures and redundant systems. Elements of statistics. Bayesian methods in engineering. Methods for reliability and risk assessment of complex systems, (event-tree and fault-tree analysis, common-cause failures, human reliability models). Uncertainty propagation in complex systems (Monte Carlo methods, Latin hypercube sampling). Introduction to Markov models. Examples and applications from nuclear and other industries, waste repositories, and mechanical systems. Open to qualified undergraduates.
M. W. Golay

22.39 Integration of Reactor Design, Operations, and Safety
______

Graduate (Fall)
Prereq: 22.211, 22.312
Units: 3-2-7
Lecture: TR2.30-4 (24-115)
______
Integration of reactor physics and engineering sciences into nuclear power plant design focusing on designs that are projected to be used in the first half of this century. Topics include materials issues in plant design and operations, aspects of thermal design, fuel depletion and fission-product poisoning, and temperature effects on reactivity. Safety considerations in regulations and operations such as the evolution of the regulatory process, the concept of defense in depth, general design criteria, accident analysis, probabilistic risk assessment, and risk-informed regulations.
R. Ballinger
No textbook information available

22.40[J] Fundamentals of Advanced Energy Conversion
______

Graduate (Spring)
(Same subject as2.62[J],10.392[J])
(Subject meets with2.60[J],10.390[J])
Prereq: 2.006, or 2.051 and 2.06, or permission of instructor
Units: 4-0-8
______
Fundamentals of thermodynamics, chemistry, and transport applied to energy systems. Analysis of energy conversion and storage in thermal, mechanical, chemical, and electrochemical processes in power and transportation systems, with emphasis on efficiency, performance and environmental impact. Applications to fuel reforming and alternative fuels, hydrogen, fuel cells and batteries, combustion, catalysis, combined and hybrid power cycles using fossil, nuclear and renewable resources. CO2 separation and capture. Biomass energy. Meets with 2.60 when offered concurrently; students taking the graduate version complete additional assignments.
A. F. Ghoniem, W. Green

Radiation Interactions and Applications

22.51 Quantum Theory of Radiation Interactions
______

Graduate (Fall)
Prereq: 22.11
Units: 3-0-9
Lecture: MW11-12.30 (24-121)
______
Introduces elements of applied quantum mechanics and statistical physics. Starting from the experimental foundation of quantum mechanics, develops the basic principles of interaction of electromagnetic radiation with matter. Introduces quantum theory of radiation, time-dependent perturbation theory, transition probabilities and cross sections. Applications are to controlling coherent and decoherent dynamics with examples from quantum information processing.
P. Cappellaro
No required or recommended textbooks

22.55[J] Radiation Biophysics
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject asHST.560[J])
(Subject meets with22.055)
Prereq: Permission of instructor
Units: 3-0-9
______
Provides a background in sources of radiation with an emphasis on terrestrial and space environments and on industrial production. Discusses experimental approaches to evaluating biological effects resulting from irradiation regimes differing in radiation type, dose and dose-rate. Effects at the molecular, cellular, organism, and population level are examined. Literature is reviewed identifying gaps in our understanding of the health effects of radiation, and responses of regulatory bodies to these gaps is discussed. Students taking graduate version complete additional assignments.
Staff

22.56[J] Noninvasive Imaging in Biology and Medicine
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject as9.173[J],20.483[J],HST.561[J])
Prereq: 18.03, 8.03, or permission of instructor
Units: 3-0-9
______
Background in the theory and application of noninvasive imaging methods in biology and medicine, with emphasis on neuroimaging. Focuses on the modalities most frequently used in scientific research (x-ray CT, PET/SPECT, MRI, and optical imaging), and includes discussion of molecular imaging approaches used in conjunction with these scanning methods. Lectures are supplemented by in-class discussions of problems in research and demonstrations of imaging systems.
A. Jasanoff

22.561[J] Magnetic Resonance Analytic, Biochemical, and Imaging Techniques
______

Not offered academic year 2016-2017Graduate (Spring)
(Same subject asHST.584[J])
Prereq: Permission of instructor
Units: 3-0-12
______
Introduction to basic NMR theory. Examples of biochemical data obtained using NMR summarized along with other related experiments. Detailed study of NMR imaging techniques includes discussions of basic cross-sectional image reconstruction, image contrast, flow and real-time imaging, and hardware design considerations. Exposure to laboratory NMR spectroscopic and imaging equipment included.
L. Wald, K. Setsompop

22.562 Spatial Aspects of Nuclear Magnetic Resonance Spectroscopy
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 18.03, 8.05
Units: 3-0-9
______
Discusses the theory and application of nuclear magnetic resonance spectroscopy to questions of the spatial distribution of spins. Covers NMR imaging, localized spectroscopy, and local geometries as determined by diffusive processes. The theory is discussed in terms of the density operator and reciprocal space (for both imaging and motional studies). Describes applications to rapid imaging, dynamic imaging, microscopy, and localized spectroscopy. Instrumentation and experimental constraints are also described.
Staff


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Produced: 29-SEP-2016 06:37 AMFall 2016 Course 22: Nuclear Science and Engineering
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Course 22: Nuclear Science and Engineering
Fall 2016


Plasmas and Controlled Fusion

22.611[J] Introduction to Plasma Physics I
______

Graduate (Fall)
(Same subject as8.613[J])
Prereq: 6.013 or 8.07; 18.04 orCoreq: 18.075
Units: 3-0-9
URL: http://web.mit.edu/physics/subjects/index.html
Lecture: TR11-12.30 (NW16-213)
______
Introduces plasma phenomena relevant to energy generation by controlled thermonuclear fusion and to astrophysics. Elementary plasma concepts, plasma characterization. Motion of charged particles in magnetic fields. Coulomb collisions, relaxation times, transport processes. Two-fluid hydrodynamic and MHD descriptions. Plasma confinement by magnetic fields, simple equilibrium and stability analysis. Wave propagation in a magnetic field; application to RF plasma heating. Introduction to kinetic theory; Vlasov, Boltzmann and Fokker-Planck equations; relation of fluid and kinetic descriptions. Electron and ion acoustic plasma waves, Landau damping.
A. White
Textbooks (Fall 2016)

22.612[J] Introduction to Plasma Physics II
______

Graduate (Spring)
(Same subject as8.614[J])
Prereq: 6.651J, 8.613J, or 22.611J
Units: 3-0-9
______
Linear waves and instabilities in magnetized plasma; solutions of Vlasov-Maxwell equations in homogeneous and inhomogeneous plasmas; conservation principles for energy and momentum; quasi-linear theory and nonlinear stabilization; solitons and coherent nonlinear phenomena; collisions and discrete particle effects; fluctuations in a stable plasma; Fokker-Planck equation and transport phenomena. A subject description tailored to fit the background and interests of the attending students distributed shortly before and at the beginning of the subject.
Staff

22.615 MHD Theory of Fusion Systems
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 22.611J, 6.651J, or 8.613J
Units: 3-0-9
______
Discussion of MHD equilibria in cylindrical, toroidal, and noncircular configurations. MHD stability theory including the Energy Principle, interchange instability, ballooning modes, second region of stability, and external kink modes. Description of current configurations of fusion interest.
N. Louriero

22.616 Plasma Transport Theory
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 22.615
Units: 3-0-9
______
The Fokker-Planck operator for Coulomb collisions, including the Landau and Rosenbluth potential forms, is derived, expanded to obtain useful limits, and used to define characteristic times. Classical collisional transport in an arbitrary magnetic field is developed first, and then the high (Pfirsch-Schluter), low (banana), and intermediate (plateau) collisionality regimes of tokamak transport are examined with emphasis on the banana regime where bootstrap current is most pronounced. Gyrokinetics and zonal flow is discussed.
Staff

22.617 Plasma Turbulence and Transport
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: 22.616 or permission of instructor
Units: 3-0-9
______
Introduces plasma turbulence and turbulent transport, with a focus on fusion plasmas. Covers theory of mechanisms for turbulence in confined plasmas, fluid and kinetic equations, and linear and nonlinear gyrokinetic equations; transport due to stochastic magnetic fields, magnetohydrodynamic (MHD) turbulence, and drift wave turbulence; and suppression of turbulence, structure formation, intermittency, and stability thresholds. Emphasis on comparing experiment and theory. Discusses experimental techniques, simulations of plasma turbulence, and predictive turbulence-transport models.
Staff

22.62 Fusion Energy
______

Graduate (Spring)
Prereq: 22.611
Units: 3-0-9
______
Basic nuclear physics and plasma physics for controlled fusion. Fusion cross sections and consequent conditions required for ignition and energy production. Principles of magnetic and inertial confinement. Description of magnetic confinement devices: tokamaks, stellarators and RFPs, their design and operation. Elementary plasma stability considerations and the limits imposed. Plasma heating by neutral beams and RF. Outline design of the ITER "burning plasma" experiment and a magnetic confinement reactor.
J. Freidberg

22.63 Engineering Principles for Fusion Reactors
______

Not offered academic year 2016-2017Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Fusion reactor design considerations: ignition devices, engineering test facilities, and safety/environmental concerns. Magnet principles: resistive and superconducting magnets; cryogenic features. Blanket and first wall design: liquid and solid breeders, heat removal, and structural considerations. Heating devices: radio frequency and neutral beam.
D. Whyte

22.67 Principles of Plasma Diagnostics
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: 6.651J, 8.613J, or 22.611J
Units: 3-0-9
______
Introduction to the physical processes used to measure the properties of plasmas, especially fusion plasmas. Measurements of magnetic and electric fields, particle flux, refractive index, emission and scattering of electromagnetic waves and heavy particles; their use to deduce plasma parameters such as particle density, pressure, temperature, and velocity, and hence the plasma confinement properties. Discussion of practical examples and assessments of the accuracy and reliability of different techniques.
I. Hutchinson

Nuclear Materials

22.71[J] Modern Physical Metallurgy
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as3.40[J])
(Subject meets with3.14)
Prereq: 3.022, 3.032
Units: 3-0-9
Subject Cancelled Subject Cancelled
______
Examines how the presence of 1-, 2- and 3-D defects and second phases control the mechanical, electromagnetic and chemical behavior of metals and alloys. Considers point, line and interfacial defects in the context of structural transformations including annealing, spinodal decomposition, nucleation, growth, and particle coarsening. Concentrates on structure-function relationships, and in particular how grain size, interstitial and substitutional solid solutions, and second-phase particles impact mechanical and other properties Industrially relevant case studies illustrate lecture concepts. Students taking the graduate version explore the subject in greater depth.
C. Tasan

22.72[J] Corrosion: The Environmental Degradation of Materials
______

Not offered academic year 2017-2018Graduate (Spring)
(Same subject as3.54[J])
Prereq: 3.012
Units: 3-0-9
______
Applies thermodynamics and kinetics of electrode reactions to aqueous corrosion of metals and alloys. Application of advanced computational and modeling techniques to evaluation of materials selection and susceptibility of metal/alloy systems to environmental degradation in aqueous systems. Discusses materials degradation problems in marine environments, oil and gas production, and energy conversion and generation systems, including fossil and nuclear.
R. G. Ballinger

22.73[J] Defects in Materials
(New)
______

Graduate (Fall)
(Same subject as3.33[J])
Prereq: 3.21, 3.22
Units: 3-0-9
Lecture: F11-12.30 (24-121) Recitation: F EVE (4.30-6 PM) (24-115) +final
______
Examines point, line, and planar defects in structural and functional materials. Relates their properties to transport, radiation response, phase transformations, semiconductor device performance and quantum information processing. Focuses on atomic and electronic structures of defects in crystals, with special attention to optical properties, dislocation dynamics, fracture, and charged defects population and diffusion. Examples also drawn from other systems, e.g., disclinations in liquid crystals, domain walls in ferromagnets, shear bands in metallic glass, etc.
J. Li
No textbook information available

22.74[J] Radiation Damage and Effects in Nuclear Materials
______

Not offered academic year 2016-2017Graduate (Fall)
(Same subject as3.31[J])
Prereq: 22.14, 3.21, or permission of instructors
Units: 3-0-9
______
Studies the origins and effects of radiation damage in structural materials for nuclear applications. Radiation damage topics include formation of point defects, defect diffusion, defect reaction kinetics and accumulation, and differences in defect microstructures due to the type of radiation (ion, proton, neutron). Radiation effects topics include detrimental changes to mechanical properties, phase stability, corrosion properties, and differences in fission and fusion systems. Term project required.
M. Short

22.76 Nuclear Chemical Engineering
______

Not offered academic year 2016-2017Graduate (Fall)
Prereq: Permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/22.76/www/
______
Application of chemical engineering to nuclear fission reactors and nuclear waste reprocessing. Review of chemical kinetics, equilibrium, and thermodynamics. Chemistry of inorganic elements used in nuclear technology. Principles of chemical separation of radioactive waste. Examination of separation engineering processes. Isotopic enrichment techniques and processes. Chemical behavior of stable elements and radionuclides in reactor conditions. Laboratory demonstration of radioisotope separations.
Staff

22.78 Principles of Nuclear Chemical Engineering and Waste Management
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Introduces scientific and engineering aspects of chemical engineering and waste management applied to reactors and the fuel cycle. Includes chemical behavior in reactors (normal and accident), spent nuclear fuel aging, separation processes in reprocessing, and waste treatment processes. Addresses management of radioactive wastes, including waste forms, classification, fundamental principles, governing equations for radionuclide transport in the environment, performance assessment of geological waste disposal systems, and implications of advanced fuel cycles.
C. Forsberg

Systems, Policy, and Economics

22.811[J] Sustainable Energy
______

Graduate (Fall)
(Same subject as1.818[J],2.65[J],10.391[J],11.371[J])
(Subject meets with2.650[J],10.291[J],22.081[J])
Prereq: Permission of instructor
Units: 3-1-8
URL: http://web.mit.edu/10.391J/www/
Lecture: TR3-5 (32-155) Recitation: F1 (32-144)
______
Assessment of current and potential future energy systems. Covers resources, extraction, conversion, and end-use technologies, with emphasis on meeting 21st-century regional and global energy needs in a sustainable manner. Examines various energy technologies in each fuel cycle stage for fossil (oil, gas, synthetic), nuclear (fission and fusion) and renewable (solar, biomass, wind, hydro, and geothermal) energy types, along with storage, transmission, and conservation issues. Emphasizes analysis of energy propositions within an engineering, economic and social context. Students taking graduate version complete additional assignments.
M. W. Golay
Textbooks (Fall 2016)

22.812 Managing Nuclear Technology
______

Not offered academic year 2017-2018Graduate (Spring)
Prereq: Permission of instructor
Units: 3-0-9
______
Examines current economic, management, and policy issues concerning nuclear power and its fuel cycle. Introduces methods for analyzing private and public policy alternatives, including techniques in economic and financial analysis. Application to specific problem areas, including nuclear waste management, weapons proliferation, and the economic competitiveness of nuclear power. Other topics include deregulation and restructuring in the electric power industry.
R. K. Lester

22.813[J] Energy Technology and Policy: From Principles to Practice
______

Graduate (Spring)
(Same subject as5.00[J],6.929[J],10.579[J])
Prereq: None
Units: 3-0-6
______
Develops analytical skills to lead a successful technology implementation with an integrated approach that combines technical, economical and social perspectives. Considers corporate and government viewpoints as well as international aspects, such as nuclear weapons proliferation and global climate issues. Discusses technologies such as oil and gas, nuclear, solar, and energy efficiency. Limited to 100.
J. Deutch

22.814 Nuclear Non-Proliferation
______

Graduate (Spring)
Prereq: None
Units: 4-0-8
______
Examines the historical development of nuclear weapons, the policies and technical strategies currently in place to secure and control the movement of nuclear materials, and the short- and long-term effects of weapons utilized under different scenarios. Considers issues such as how to restrict the global proliferation of nuclear weapons, whether nuclear energy can be made proliferation-proof and what has changed in the wake of the Cold War, as well as lessons to be learned from past experience. Emphasizes advanced approaches to both production and detection of nuclear materials.
R. S. Kemp, A. Danagoulian

General

22.90 Nuclear Science and Engineering Laboratory
______

Graduate (Fall)
(Subject meets with22.09)
Prereq: permission of instructor
Units: 2-6-4
Lecture: M1-3 (NW12-222) Lab: W12-3 (NW12-222) or F12-3 (NW12-222)
______
See description under subject 22.09.
A. Danagoulian, G. Kohse
No textbook information available

22.901 Independent Project in Nuclear Science and Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
For graduate students who wish to conduct a one-term project of theoretical or experimental nature in the field of nuclear engineering, in close cooperation with individual staff members. Topics and hours arranged to fit students' requirements. Projects require prior approval.
J. Li
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

22.911 Seminar in Nuclear Science and Engineering
______

Graduate (Fall) Can be repeated for credit
Prereq: None
Units: 2-0-1 [P/D/F]
Lecture: W12.30-2.30 (24-121) or W EVE (4-6 PM) (24-115)
______
No required or recommended textbooks

22.912 Seminar in Nuclear Science and Engineering
______

Graduate (Spring) Can be repeated for credit
Prereq: None
Units: 2-0-1 [P/D/F]
______
Restricted to graduate students engaged in doctoral thesis research.
C. Forsberg, I. Hutchinson, P. Cappellaro

22.921 Nuclear Power Plant Dynamics and Control
______

Graduate (IAP)
Prereq: None
Units: 1-0-2
______
Introduction to reactor dynamics, including subcritical multiplication, critical operation in absence of thermal feedback effects and effects of xenon, fuel and moderator temperature, etc. Derivation of point kinetics and dynamic period equations. Techniques for reactor control including signal validation, supervisory algorithms, model-based trajectory tracking, and rule-based control. Overview of light-water reactor start-up. Lectures and demonstrations with use of the MIT Research Reactor. Open to undergraduates with permission of instructor.
J. A. Bernard

22.93 Teaching Experience in Nuclear Science & Engineering
______

Graduate (Fall, Spring, Summer)
Prereq: Permission of department
Units arranged
TBA.
______
For qualified graduate students interested in teaching as a career. Classroom, laboratory, or tutorial teaching under the supervision of a faculty member. Students selected by interview. Credits for this subject may not be used toward master's or engineer's degrees. Enrollment limited by availability of suitable teaching assignments.
D. Whyte
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

22.94 Research in Nuclear Science and Engineering
______

Graduate (Fall, Spring, Summer) Can be repeated for credit
Prereq: Permission of research supervisor
Units arranged [P/D/F]
TBA.
______
For research assistants in Nuclear Science and Engineering who have not completed the NSE doctoral qualifying exam. Hours arranged with and approved by the research supervisor. Units may not be used towards advanced degree requirements.
J. Li
No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

22.S902-22.S905 Special Subject in Nuclear Science and Engineering
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
22.S902: TBA.
22.S903: TBA.
22.S904: TBA.
22.S905: TBA.
______
Seminar or lecture on a topic in nuclear science and engineering that is not covered in the regular curriculum. 22.S905 is graded P/D/F.
J. Li
22.S902: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
22.S903: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
22.S904: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)
22.S905: No textbook information available (Summer 2016); No required or recommended textbooks (Fall 2016)

22.THG Graduate Thesis
______

Graduate (Fall, IAP, Spring, Summer) Can be repeated for credit
Prereq: Permission of instructor
Units arranged
TBA.
______
Program of research, leading to the writing of an SM, NE, PhD, or ScD thesis; to be arranged by the student and an appropriate MIT faculty member. Consult department graduate office.
J. Li
Textbooks arranged individually (Summer 2016); No required or recommended textbooks (Fall 2016)


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Produced: 29-SEP-2016 06:37 AM